AS3525-A/-B C22O22 Data Sheet, Confidential å Datasheet, Confidential AS3525 Advanced Audio Processor System 1 Description This highly flexible and fully integrated audio processor system (AS3525) combines strong calculating power, high performance audio features with system power management options for battery powered devices. 2 Key Features 2.1 Digital Core Embedded 32-Bit RISC Controller Using advanced 0.13µm process technology and large on chip RAM leads to outstanding low power consumption of as low as 58mW for a complete flash-player during MP3 playback. Based on a powerful ARM9TDMI capable of performing up to 200MIPS it is suited to run MP3, AAC, WMA, OGG… decoders and encoders and, in addition, it can perform extensive user interfaces, motion graphics support, video playback and much more. The AS3525 SOC (system-on-a-Chip) features dedicated high speed interfaces for ATA IDE, USB2.0 HS-OTG and SDRAM ensuring maximum performance for download, upload, and playback. Furthermore interfaces for NAND flashes, MMC/SD cards and Memory Stick ensure most flexible system design possibilities. Hardware support for parallel interfaces lower the CPU load serving complex and/or colour user interfaces. • ARM922TDMI RISC CPU • 2.5Mbit on-chip RAM • 1Mbit on chip ROM • Clock speed max. 250MHz (200MIPS) • Standard JTAG interface USB 2.0 HS & OTG Interface Additional serial high-speed data and control interfaces guarantee the connection to other peripherals and or processors in the system. • Up to 480Mbit/s transfer speed • USB 2.0 HS/FS physical inlcuding OTG support • USB 2.0 HS/FS digital core including OTG host • Dedicated dual port buffer RAM • DMA bus master functionality IDE Host Controller Two independently programmable PLLs generate the required frequencies for audio playback/recording, for the processor core and for the USB interface at the same time. An additional external clock input eliminates the use of external crystals when used in multi-processor systems like mobile phones. • Supporting Ultra ATA 33/66/100/133 modes • Programmable IO and Multi-word DMA capability • Dedicated dual port buffer RAM • DMA bus master functionality External Memory Controller It has a variety of audio inputs and outputs to directly connect electret microphones, and auxiliary signal sources via a 10-channel mixer to a 16Ω/32Ω headset , 4Ω speaker or auxiliary audio peripherals. • Dynamic memory interface • Asynchronous static memory • DMA bus master functionality DMA Controller Further the device offers advanced power management functions. All necessary ICs and peripherals in a Digital Audio Player with flash or hard-disk memory are supplied by the AS3525. The different regulated supply voltages are fully programmable. The power management block generates 10 different supply voltages out of a single battery supply. CPU, NAND flash, SRAM, memory cards, LCD, LCD backlight and USB-OTG can be powered. When operating from a single cell (AA or AAA) battery the AS3525 can use a DCDC booster to generate the needed system supply. • Single Master DMA controller • 2 DMA channels possible at the same time • 16 DMA requests supported Interrupt Controller The AS3525 has an independent 32kHz real time clock (RTC) on chip, which allows a complete power down of the system CPU and peripherals. AS3525 also contains a charger for Li-Io battery supply The single supply voltage may vary from 1.0V to 5.5V. • Support for 32 standard interrupts • Support for 16 vectored IRQ interrupts Audio Subsystem Interface • Dedicated 2 wire serial control master • I2S input and output with dual port buffer RAM Nand Flash Interface • 8 and 16bit flash support • 3, 4 & 5 byte address support • hardware ECC MMC/SD Interface • • MMC/SD Card host for multiple card support 4 data line support for SD cards © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 1 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 2.3 MS / MS Pro Interface • Dedicated dual port buffer RAM Display Interface • Serial and parallel controller supported • On chip hardware acceleration Synchronous Serial Interface • Master and slave operation • 8 and 16 bit support • Several protocol standards supported I2S Interface • Input multiplexed with audio subsystem • selectable SPDIF input conversion • Dedicated dual port buffer RAM 2 Wire Serial Control Interface • Master and slave operation • Standard and fast mode support General Purpose IO Interface • 4x 8-bit ports 2.2 Audio Multi-bit Sigma Delta Converters • DAC: 18bit with 94dB SNR (‘A’ weighted) • ADC: 14bit with 82dB SNR (‘A’ weighted) • Sampling Frequency: 8-48kHz • 32 gain steps @ 1.5dB and MUTE 2 Line Inputs • stereo, 2x mono or mono differential inputs • 32 gain steps @ 1.5dB and MUTE 2 Microphone Inputs • differential inputs • 3 gain pre-sets (28/34/40 dB) and OFF with AGC • 32 gain steps @ 1.5dB and MUTE • microphone detection with about 50uA • supply for electret microphone max 1mA • remote control by switch Line Output • max 1Vp @ 10kΩ in single ended stereo mode • >32Ω in mono differential mode to drive ear-pieces • 32 gain steps @ 1.5dB and MUTE Stereo Headphone Audio Amplifier • 2x 60mW @ 16Ω driver capacity • 32 gain steps @ 1.5dB and MUTE • Click- and pop-less start-up and power down • Headphone and over-current detection • Phantom ground eliminates large capacitors Stereo Speaker Audio Amplifier • 2x 500mW @ 4Ω driver capacity • 32 gain steps @ 1.5dB and MUTE • Click- and pop-less start-up and power down • Over-current detection 10 Channel Audio Mixer • • • mixes Line inputs, Mic inputs and DAC output separate selectable source for right and left channel possibility to select AGC to prevent clipping Power Management Voltage Generation • step up for system supply (3.0V-3.6V, 150mA) • charge-pump for CPUcore (1.05V-1.2V, 50mA) • charge pump for USB OTG (5V, 10mA) • LDO for digital supply (2.9V, 200mA) • LDO for analog supply (2.9V, 200mA) • LDO for IO supply (2.94 or 3.11V, 200mA) • LDO for peripherals (1.7V-3.3V, 200mA) • LDO for USB Transceiver (3.26V, 200mA) • LDO for RTC (1.0V-2.5V, 2mA) 15V Back-light step up converter • for driving up to 6 white LEDs in series to achieve a uniform illumination • current programmable up to 40mA (1.25mA steps) Li-Io Battery Charger • • • automatic 50mA trickle charging prog. constant current charging (50 – 400mA) prog. constant voltage charging (3.9 - 4.25V) 2.4 System RTC • ultra low power 32kHz oscillator • 32bit RTC second counter • selectable alarm (seconds or minutes) • trim able oscillator Oscillator • low power 12-24MHz Oscillator • generating main system clock Supervisor • automatic battery monitoring with interrupt generation and selectable warning level • automatic temperature supervision with interrupt generation and selectable warning and shutdown levels General Purpose ADC • 10bit resolution • 16 inputs analog multiplexer UID • Unique Identification Number in OTP ROM for DRM support General • Reset pin, watchdog • 10sec emergency shut-down • Wide battery supply range 1V – 5.5V • MP3 playback with 58mW Packages: • • 3 • • • • AS3525-A: CTBGA224 13x13mm, 0.8mm pitch AS3525-B: CTBGA144 10x10mm, 0.8mm pitch Application Portable Digital Audio Player and Recorder Portable Digital Media Player PDA Smartphone © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 2 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 4 Figure 1 Block Diagram AS3525 Block Diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 3 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table of Contents 1 DESCRIPTION 1 2 KEY FEATURES 1 2.1 Digital Core 1 2.2 Audio 2 2.3 Power Management 2 2.4 System 2 3 APPLICATION 2 4 BLOCK DIAGRAM 3 5 TYPICAL APPLICATIONS 9 5.1 Flash-Player 9 5.2 Hard-Disk-Player 6 ELECTRICAL SPECIFICATIONS 6.1 Absolute Maximum Ratings 6.2 Operating Conditions 6.2.1 Supply Voltages 6.2.2 Internal Supply Voltages 6.2.3 Power Management Output Voltages 6.2.4 Operating Currents 6.2.5 Temperature Range 6.2.6 Audio Specification 7 DETAILED FUNCTIONAL DESCRIPTIONS 10 11 11 12 12 12 13 14 14 15 17 7.1 ARM922-T Processor Core 7.1.1 General 7.1.2 Block Diagrams 7.1.3 ARM922T Details 7.1.4 ARM V4T Architecture 7.1.5 JTAG Interface 7.1.6 Boot Concept 17 17 18 19 19 21 22 7.2 AHB Peripheral Blocks 7.2.1 2.5 MBIT RAM Main Memory 7.2.2 On-Chip ROM 7.2.3 VIC – Vectored Interrupt Controller 7.2.4 SMDMAC - Single master DMAC 7.2.5 Multi Port Memory Controller (MPMC) 24 24 25 25 27 29 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 4 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.6 7.2.7 7.2.8 IDE Interface USB 2.0 HS OTG interface Memory Stick / Memory Stick Pro Interface 30 33 38 7.3 APB Peripheral Block 7.3.1 Timers 7.3.2 Watchdog Unit 7.3.3 SSP – Synchronous Serial Port 7.3.4 GPIO - General purpose input/output ports 7.3.5 MCI – SD / MMC Card Interface 7.3.6 I2cAudMas - I2C audio master interface 7.3.7 I2CMSI - I2C master/slave interface 7.3.8 I2SIN - I2S input interface 7.3.9 SPDIF interface 7.3.10 I2SOUT - I2S output interface 7.3.11 NAND Flash Interface 7.3.12 DBOP - Data Block Output Port 7.3.13 UART – Universal Asynchronous Receiver/Transmitter 7.3.14 CGU - Clock generation unit 7.3.15 CCU - Chip Control Unit 40 40 44 47 49 56 57 58 59 65 66 72 83 93 100 114 7.4 Audio and Power Management functions 7.4.1 SYSTEM 7.4.2 3V Step-Up Converter 7.4.3 Low Drop Out Regulators 7.4.4 Charge-Pump Step-Down Converter 7.4.5 Audio Line Output 7.4.6 Headphone Output 7.4.7 Speaker Output 7.4.8 Microphone Inputs (2x) 7.4.9 Audio Line Inputs (2x) 7.4.10 I2S Digital Audio Interface 7.4.11 Audio Output Mixer 7.4.12 Audio Settings 7.4.13 VBUS CP & Comparator 7.4.14 Auxiliary Oscillator 7.4.15 Charger 7.4.16 15V Step-Up Converter 7.4.17 Supervisor 7.4.18 Interrupt Generation 7.4.19 Real Time Clock 7.4.20 10-Bit ADC 7.4.21 128 bit OTP ROM 7.4.22 2-Wire-Serial Control Interface 119 119 121 123 126 129 131 134 138 141 143 147 148 150 151 152 154 156 157 162 164 167 168 8 PINOUT AND PACKAGING 8.1 Package Variants 172 172 8.2 CTBGA224 Package Drawings 8.2.1 Marking 8.2.2 CTBGA224 Package Ball-out 8.2.3 CTBGA224 Ball List 172 172 173 173 8.3 CTBGA144 Package Drawings 8.3.1 CTBGA144 Package Ball-out 8.3.2 CTBGA144 Ball List 182 182 183 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 5 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 8.4 Pad Cell Description 8.4.1 Digital Pads 189 189 9 APPENDIX 190 9.1 Memory MAP 190 9.2 Register definitions 9.2.1 Base Address definitions 191 192 10 ORDERING INFORMATION 193 11 COPYRIGHT 194 12 DISCLAIMER 194 13 CONTACT INFORMATION 194 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 6 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Document Revisions Revision 0.1 Chapter all Date 9.12.2004 0.2 4,6.6 19.12.2004 mma application figures, register base address 0.3 7.6, 7.7 28.1.2005 mma CTBGA144 ball-out added 0.4 6.2 7.3.2005 mma changes in boot-concept 0.5 6.4.14 24.3.2005 mma CGU frequency settings updated 0.6 6.2, 7.4 1.4.2005 mma correct IntBootSel 0.6 7.7 1.4.2005 mma Package Code and Marking added 0.7 6.7 – 6.28 2.5.2005 mma Parameters updated 0.7 5.1.2. 2.5.2005 mma Supply Currents added 0.7 6.15 5.5.2005 mma Audio Specification added 0.8 7.4, 7.7 21.6.2005 mma tmsel PAD-type is pull down 0.8 5 28.7.2005 mma Lead temperature corrected for lead-free package 0.8 5.0, 5.1 5.8.2005 wsg 0.82 7.8 6.10.2005 pkm Added conditions for absolute max rating of vdd_peri, vdd_mem, vdd_core, usb_vdda_33t, usb_vdda_33c. Changed operating condition for vdd_core max limit. added pad cell description 0.82 7 13.10.2005 pkm 0.83 5.1.1 22.10.2005 wsg 1.00 all correct pin list pad types (JTAG_trst_n, jtag_tdi, mpmc_fbclkin, naf_bsy_n, ide_ha[0..2], ide_reset_n, id_dig) Added Note on VDD_CORE supply voltage scaling Major revision 25.9.2006 wsg added description for modified C22 bootloader 16.2.2007 wsg 22.3.2007 pkm 17.4.2007 wsg 7.4.7.2 6.7.2007 wsg 7.1.6 6.7.2007 wsg 6.2.3 24.2.2009 wsg added UART description corrected NAFmode register description added C22O22 version in order information corrected header in table “CGU frequency settings” updated ESD and soldering conditions, change ADC_10 source for C22O22 from BVDD to CHG_OUT update of PINOUT for AS3525A: test pins at K2, K4 and L2 are only used during production test and must stay unconnected for normal operation mode. Pins are now marked with NC. Added Note for AS3525B package that CVDD and vdd_core have to be connected externally! added application circuit with schottky diodes for speaker output protection. deleted description of C21O20 bootloader (this chip version is not available any more) Added definition of Power Management Output Voltages 1.11 1.13 Description wsg/pkm 1.1 1.12 Owner mma first preliminary version © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 7 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Related Documents ARM922T Technical Reference Manual DDI0184B_922T_TRM.pdf http://www.arm.com ARM9TDMI Technical Reference Manual DDI0180A_9tdmi_trm.pdf http://www.arm.com PrimeCell™ MultiPort Memory Controller; PL172 Technical Reference Manual AMBA Specification (Rev 2.0) http://www.arm.com IHI0011A_AMBA_SPEC.pdf http://www.arm.com PrimeCell™ Synchronous Serial Port; PL022 Technical Reference Manual http://www.arm.com PrimeCell™ General Purpose Input/Output; PL061 Technical Reference Manual http://www.arm.com PrimeCell™ Single Master DMA Controller; PL081 Technical Reference Manual http://www.arm.com PrimeCell™ Multimedia Card Interface; PL180 Technical Reference Manual http://www.arm.com PrimeCell™ Vectored Interrupt Controller; PL190 Technical Reference Manual http://www.arm.com CWda03 - SPDIF-AES/EBU TO I2S CONVERTER http://www.coreworks.pt TSMC TPZ013G3 Standard I/O Library Databook http://www.tsmc.com DesignWare USB 2.0 HI-SPEED ON-THE-GO Controller Subsystem http://www.synopsys.com DesignWare USB 2 PHY Hardmacro http://www.synopsys.com SMS2IP mem stick host controller http://www.sony.com ICON mem stick host con interface http://www.sony.com IDE host controller BK3710S http://www.palmchip.com © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 8 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 5 Typical Applications AS3525 is an advanced audio system-on-a-chip for flash-players, hard-disk players, mobile phones and PDAs powered by single Li+, AA or AAA batteries. AS3525-A is the package variant with 224 balls intended for full-featured harddisk players, AS3524-B is the package variant with 144 balls for flash players with reduced feature set and no need for an external SDRAM. Two versions are available for the chips: C22O22 which is the newest version with additional boot loader features, and C21O20 which is outdated and must not be used for new design starts. 5.1 Flash-Player The following schematic shows a typical flash-player application of the AS3525-B in the CTBGA144 package. A single AAA or AA battery powers the complete system. The on-chip DC/DC converter generates a supply voltage of 3.25V (BVDD) with a maximum output load current of 150mA. Linear regulators, which are connected to this BVDD, provide the supply voltages for the analog functions, the USB-2.0-Phy, the digital periphery and external components. A highly efficient Charge-Pump Step-Down-Converter supplies the digital core. All analog features are available in this package variant. Also, the digital interfaces to NAND-flash, MMC/SD card, Memory-Stick-Pro, USB-2.0 HS&OTG, Synchronous Serial Interface, General Purpose IOs and different displays are provided. Figure 2 Flash Player Application © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 9 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 5.2 Hard-Disk-Player The following schematic shows a typical hard-disk-player application of the AS3525-A using the CTBGA224 package. A single Li+ battery powers the complete system. The Li+ cell can be charged either from a DC-supply or the USB connector. Linear regulators, which are connected to this battery voltage (BVDD), provide the supply voltages for the analog functions, the USB-2.0-Phy, the digital periphery and the SDRAM interface. A highly efficient Charge-Pump Step-Down-Converter supplies the digital core. All chip functions are available in this package variant. For lowest power consumption, it is recommended to use low voltage external SDRAMs (PVDD=1.8V). Figure 3 Hard Disk Player © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 10 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 6 Electrical Specifications 6.1 Absolute Maximum Ratings Stresses beyond those listed under “Absolute Maximum Ratings“ may cause permanent damage to the device. These are stress ratings only. Functional operation of the device at these or any other conditions beyond those indicated under “Operating Conditions” is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. The device should be operated under recommended operating conditions. Table 1 Absolute Maximum Ratings Symbol V IN_SUP Parameter digital supply pins Min -0.5 Max 3.7 Unit V V IN_CORE digital core supply pins -0.5 1.68 V Note Applicable for pins vdd_peri, vdd_mem, usb_vdda33t1, usb_vdda33t2, usb_vdda33t3, usb_vdda33c Applicable for pins vdd_core V IN_VB1V single cell supply voltage -0.5 5.0 V Applicable for pin VBAT_1V V IN_5V 5V pins -0.5 7.0 V V IN_SW15 15V pin -0.5 17 V Applicable for pins BVDD, CHG_IN, VBUS Applicable for pins SW15 V IN_VSS Voltage difference at VSS terminals -0.5 0.5 V V IN_DVDD 3.3V pins with diode to DVDD -0.5 5.0 DVDD+0.5 V V IN_xDVDD pins with no diode to DVDD -0.5 7.0V V V IN_AVDD 3.3V pins with diode to AVDD -0.5 5.0 AVDD+0.5 V V IN_REG voltage regulator pins with diodes to BVDD voltage regulator pin with diode to BVDD pins with diode to BVDD -0.5 5.0 BVDD+0.5 3.6 BVDD+0.5 7.0 BVDD+0.5 100 V mA Applicable for pins LSPR/L, HPR/L, CHG_OUT, SW3 Norm: JEDEC 17 +/-1 kV Norm: JEDEC JESD22-A114C (1) +/-2 kV 1000 mW Norm: JEDEC JESD22-A114C (Pins: usb_dp, usb_dm, usb_vbus) Valid for CTBGA144 package 85 % V IN_RVDD V IN_BVDD I scr Input Current (latchup immunity) Electrostatic Discharge HBM ESD ESD_USB Pt H (1) Electrostatic Discharge HBM for USB Pins Total Power Dissipation (all supplies and outputs) Humidity non-condensing -0.5 -0.5 -100 5 V V Applicable for pins VSS3,VSS15, VSSCP, BVSS, BVSS2, AVSS, DVSS, vss_core, vss_peri, vss_mem, usb_vssa33t, usb_vssa33c Applicabel for pins MCLK, LRCK, SCLK, SDI, P_PVDD, BATTEMP, ISINK, XIN_32K, XOUT_32K, XIN_24M, XOUT_24M, INTRQ, XRES, CP_1V, CN_1V, CN_5V Applicable for pins CSCL, CSDA, PWR_UP, CP_5V Applicable for pins BGND, HPH_CM, HPGD, LOUTL/R, VREF, AGND, LIN1L/R, LIN2L/R, MIC1_P/N, MIC2_P/N, MSUP1, MSUP2 Applicable for pins AVDD, QLDO2, DVDD, PVDD, CPVDD, CVDD, UVDD Applicable for pins RVDD Electrostatic discharge of XIN24 and XOUT24 pin is +/-600V for C21O20 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 11 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 2 Soldering Conditions Symbol Parameter T body Package Body Temperature T peak Min Max 260 Unit °C 235 245 °C 30 45 s Solder Profile* D well Note Norm IPC/JEDEC J-STD-020C, reflects moisture sensitivity level only above 217 °C * austriamicrosystems AG strongly recommends to use underfill. 6.2 Operating Conditions 6.2.1 Supply Voltages Table 3 Operating conditions for supply input voltages Symbol VB1V Parameter DCDC Supply Voltage Min 1.0 Max 3.6 Unit V BVDD Battery Supply Voltage 3.2 5.5 V VBUS USB VBUS Voltage 4.0 5.5 V CHGIN Charger Supply Voltage 4.5 5.5 V Difference of Negative Supplies VSS3, VSS1, VSS15, BVSS, BVSS2, AVSS, DVSS, VSSCP -0.1 0.1 V Note To achieve good performance, the negative supply terminals should be connected to low impedance ground plane. 6.2.2 Internal Supply Voltages Following supply voltages for the digital system are generated by the integrated power management Table 4 Operating conditions for internal internal supply voltages Symbol VDD peri Min 3.0 Max 3.6 Unit V DVDD Digital Supply Voltage 2.8 3.6 V Note digital periphery supply voltage to be connected to IOVDD digital IO supply for MPMC PADs to be connected to PVDD digital core supply voltage to be connected to CVDD; see Note (1) USB analog supply transmit block to be connected to UVDD USB analog supply common block to be connected to UVDD Digital Audio Supply Voltage (LDO2) VDD mem 1.7 3.6 V VDD core 1.08 1.26 V USBVDDA33 T 3.15 3.45 V USBVDDA33 C 3.15 3.45 V AVDD Analogue Supply Voltage 2.8 3.6 V Analog Audio Supply Voltage (LDO1) Difference of Negative Supplies vss_peri, vss_core, vss_mem, usb_vssa33c, usb_vssa33t -0.1 0.1 V To achieve good performance, the negative supply terminals should be connected to low impedance ground plane. Note(s) Parameter (1) For the VDD_CORE supply, voltage scaling should be applied to optimize power consumption and CPU speed performance. For normal operation with fclk (CPU ARM-922T clock) frequencies below 200 MHz, CVDD (supply of VDD_CORE) can be set to a lower value of 1.10 V. Only for setting fclk of the CPU to clock frequencies above 200 MHz, the VDD_CORE supply voltage must be set to 1.20 V typical conditions. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 12 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 6.2.3 Power Management Output Voltages Following voltages are generated by the integrated power management blocks. Table 5 Power Management – Output Voltages Symbol Parameter Condition min. typ. max. Unit bits CVDDp[1:0]=00 1.16 1.20 1.24 V bits CVDDp[1:0]=01 1.10 1.15 1.30 V bits CVDDp[1:0]=10 see Note (1) 1.06 1.10 1.14 V bits CVDDp[1:0]=11 see Note (1) 1.01 1.05 1.09 V CVDD Regulator CVDDP Core Supply Voltage Low Dropout Regulators AVDD Output Voltage LDO1 2.85 2.90 2.95 V DVDD Output Voltage LDO2 2.85 2.90 2.95 V bit PVDDp=0 1.65 1.70 1.75 V bit PVDDp=1 1.75 1.80 1.85 V bit PVDDp=0 2.69 2.74 2.80 V bit PVDDp=1 2.84 2.90 2.96 V bit PVDDp=0 3.10 3.15 3.20 V bit PVDDp=1 3.27 3.30 3.39 V bit PVDDp=0 2.45 2.50 2.55 V bit PVDDp=1 2.30 2.36 2.42 V bit IOVDDp=0 3.06 3.11 3.16 V bit IOVDDp=1 2.89 2.94 2.99 V bits DCDC3p=11 1.95 3.00 3.05 V bits DCDC3p=10 3.05 3.10 3.15 V bits DCDC3p=01 3.15 3.20 3.25 V bits DCDC3p=00 3.55 3.60 3.65 V PVDDP IOVDD Output Voltage LDO3 Output Voltage LDO4 3V Step-Up Converter BVDD Output Voltage of DCDC Step Up Converter Notes: (1) This setting must not be used for AS3525 core supply because the lower voltage limit is out of core supply specification limits. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 13 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 6.2.4 Operating Currents Table 6 Supply currents Symbol I_BVDD Parameter Total current consumption at BVDD Typ 22 Max 340 IDD_PERI_OP Unit mA (1), (2), (3) Peripheral current 2 20 mA IDD_MEM_OP External memory interface current - 20 mA (2) IDD_CORE_OP Digital core current 20 145 mA (1), (2), (3) IDD_USBA33T_OP USB transmitter current 30 mA IDD_USBA33C_OP USB common blocks current 30 mA I_Headphone Headphone current from BVDD 2 40 mA (3) I_Audio Analog audio frontend current from DVDD (2.9V) and AVDD (2.9V) 8 15 mA (1), (3) Notes Note (1) Typical condition for playback of MP3 music with 44.1 KHz / 128 kbit with 32Ω headphones. The internal charge pump generates VDD_CORE. No external SDRAM connected. USB2.0 in standby. (2) Maximum condition for ARM running at 250 MHz, AHB/APB bus and memory at 64 MHz, USB 2.0 in HS operation. For high current mode, the charge pump is disabled and IDD_CORE_OP is added to the total current consumption at BVDD. (3) For maximum value: assuming maximum output power of 2x40 mW sine-wave into headphones (16Ω). Internal loss of headphone AB amplifier is included. In the case of standby mode or in the case of configuring the device to stopped clock, following current consumption is measured. Table 7 Leakage currents Symbol IDD_PERI_LEAK Parameter Typ Max 1500 Unit IDD_MEM_LEAK 500 μA IDD_CORE_LEAK 1000 μA μA Note Including USBA33T, USBA33C 6.2.5 Temperature Range Table 8 Temperature Range T op Symbol Parameter Operating temperature range Tj Junction temperature range R th Thermal Resistance Min 0 Typ 25 0 Max 85 110 29 Unit °C Note °C °C/W For CTBGA144 package © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 14 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 6.2.6 Audio Specification Table 9 Audio Parameters Symbol Parameter DAC Input to Line Output FS Full Scale Output SNR Signal to Noise Ratio DR Dynamic Range THD Total Harmonic Distortion Line Input to Line Output FS Full Scale Output SNR Signal to Noise Ratio THD Total Harmonic Distortion CS Channel Separation DAC Input to HP Output FS Full Scale Output SNR DR Signal to Noise Ratio Dynamic Range THD Total Harmonic Distortion CS Channel Separation Line Input to HP Output FS Full Scale Output SNR DR Signal to Noise Ratio Dynamic Range THD Total Harmonic Distortion CS Channel Separation Line Input to SP Output FS Full Scale Output SNR THD CS Signal to Noise Ratio Total Harmonic Distortion Channel Separation Notes Min Typ Max Unit 1kHz FS input A-weighted, no load, silence input A-weighted, no load, -60dB FS 1kHz input 1kHz FS input 0.985 92 89 V RMS dB dB -90 dB 1kHz 1V RMS (FS) input A-weighted, no load, silence input 1kHz 1V RMS (FS) input 0.95 93 -85 89 V RMS dB dB dB R L = 32Ω R L = 16Ω A-weighted, no load, silence input A-weighted, no load, -60dB FS 1kHz input no load, 1kHz FS input 0.950 0.944 94 90 V RMS V RMS dB dB -90 -73 -66 73 66 dB dB dB dB dB 0.930 0.936 96 95 V RMS V RMS dB dB -86 -75 dB dB Pout=20mW, R L = 32Ω, f=1kHz FS input Pout=40mW, R L = 16Ω, f=1kHz FS input R L = 32Ω R L = 16Ω R L = 32Ω, 1kHz 1V RMS (FS) input R L = 16Ω, 1kHz 1V RMS (FS) input A-weighted, no load, silence input A-weighted, no load, -60dB FS 1kHz (FS) input no load, 1kHz 1V RMS input Pout=20mW, R=32Ω, 1kHz 1V RMS (FS) input Pout=40mW, R=16Ω, 1kHz 1V RMS (FS) input R L = 32Ω R L = 16Ω R L = 32Ω, 1kHz 1V RMS (FS) input R L = 16Ω, 1kHz 1V RMS (FS) input R L = 4Ω, 1kHz 1V RMS (FS) input A-weighted, no load, silence input no load, 1kHz 1V RMS (FS) input R L = 32Ω -69 -60 dB 70 62 dB dB 1.708 1.690 1.524 94 -86 70 V RMS V RMS V RMS dB dB dB © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 15 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Symbol Parameter MIC Input to ADC Output SNR Signal to Noise Ratio DR Dynamic Range THD Total Harmonic Distortion Line Input to ADC Output SNR Signal to Noise Ratio DR Dynamic Range THD Total Harmonic Distortion Notes A-weighted, no load, silence input A-weighted, no load, -60dB FS 1kHz input 1kHz 53mV RMS (FS) input A-weighted, no load, silence input A-weighted, no load, -60dB FS 1kHz input 1kHz, 1V RMS , -3dB FS input Min Typ Max Unit 74 73 dB dB -61 dB 83 82 dB dB -62 dB BVDD = 3.3V, TA= 25oC, fs=48kHz, RL= 10kΩ unless otherwise mentioned © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 16 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7 Detailed Functional Descriptions This chapter contains detailed functional descriptions of all modules of the chip. Central microcontroller is an ARM-9, all peripherals are connected to the AMBA bus which is divided into a AHB (advanced high speed bus) and APB (advanced peripheral bus) part. All audio, power management and system monitoring functions are controlled via an I2C interface (I2C audio master). This chapter includes also all detailed desciptions and performance values for these parts. 7.1 ARM922-T Processor Core 7.1.1 General The ARM922T macrocell is a high-performance 32-bit RISC integer processor combining an ARM9TDMI™ processor core with: • 8KB instruction cache and 8 KB data cache • Instruction and data Memory Management Unit (MMU) • Write buffer with 16 data words and 4 addresses • Advanced Microprocessor Bus Architecture (AMBA™) AHB interface The ARM922T provides a high-performance processor solution for open systems requiring full virtual memory management and sophisticated memory protection. The ARM922T processor core is capable of running at 250 MHz. The ARM922T hard macrocell has a very low power consumption. The integrated cache helps to significantly reduce memory bandwith demands, improving performance and minimizing power consumption. At 250 MHz the ARM922T comsumes as little as 65 mW, making it ideal for high-performance battery operated audio or video applications. The ARM core and associated bus structures are configured for little endian byte order (compatible with Windows CE™ and Symbian™ OS). Table 10 ARM 922T characteristics Cache (I/D) 8KB / 8KB MMU yes AHB yes Thumb yes mW/MHz 0.25 @ 1.2 V MHz 250 Features • • • • • • • • • 32-bit RISC architecture (ARMv4T) Harvard architecture with separated instruction (I) and data (D) caches with 8 KB each and 8-word line length Five stage pipeline (fetch, decode, execute, memory, write back) enabling high master clock speeds 32-bit ARM instruction set for maximum performance and flexibility 16-bit Thumb instruction set for increased code density Enhanced ARM architecture V4 MMU to provide translation and access permission checks for instruction and data addresses. With this MMU different operating systems (Windows CE, Symbian …) can be implemented. Industry standard AMBA bus interface (AHB and APB) Hard-macro implementation The processor core clock frequency (FCLK) is programmable up to 250MHz and the ARM922 power consumption is directly proportional to this clock frequency FCLK © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 17 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.1.2 Block Diagrams Figure 4 ARM 922T Functional Block Diagram Figure 5 ARM9TDMI Functional Block Diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 18 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.1.3 ARM922T Details Control Coprocessor (CP15) The ARM922T macrocell is based on the ARM9TDMI Harvard architecture processor core with an efficient five-stage pipeline. To reduce the effect of memory bandwidth and latency on performance, the ARM922T macrocell includes separate cachs and MMUs for both instructions and data. It also has a write buffer and physical address TAG RAM. The control coprocessor is provided for configuration of the caches, the write buffer, and other ARM922T options. Caches Two 8KB caches are implemented, one for instructions, the other for data, both with an 8-word line size. Separate buses connect each cache to the ARM9TDMI core permitting a 32 bit instruction to be fetched and fed into the Decode stage of the pipeline at the same time as a 32 bit data access for the memory stage of the pipeline. Cache lock-down is provided to permit critical code sequences to be locked into the cache to ensure predictability for real-time code. The cache replacement algorithm can be selected by the operating system as either pseudo-random or round-robin. Both caches are 64-way set-associative. Lock-down operates on a per-way basis. Write Buffer The ARM922T macrocell also incorporates a 16-data, 4address write buffer to avoid stalling the processor when writes to external memory are performed. PA TAG RAM The ARM922T macrocell implements a physical address TAG RAM (PA TAG RAM) to perform write-backs from the data cache. Eleven registers are available for program control: • • • • • • • Register 1 controls system operation parameters including endianness, cache, and MMU enable Register 2 and 3 configure and control MMU functions Register 5 and 6 provide MMU status information Register 7 and 9 are used for cache maintenance operations Register 8 and 10 are used for MMU maintenance operations Register 13 is used for fast context switching Register 15 is used for test. Debug Features The ARM9TDMI processor core incorporates an EmbeddedICE unit and EmbeddedICE-RT logic permitting both software tasks and external debug hardware to • Set hardware and software breakpoints • Perform single-stepping • Enable access to registers and memory This functionality is implemented as a coprocessor and is accessible from hardware through the JTAG port. Full-speed, real-time execution of the processor is maintained until a breakpoint is hit. At this point control is passed either to a software handler or to JTAG control. 7.1.4 ARM V4T Architecture The physical addresses of all the lines held in the data cache are stored by the PA TAG memory, removing the requirement for address translation when evicting a line from the cache. The ARM9TDMI processor core implements the ARMv4T Instruction Set Architecture (ISA). The ARMv4T ISA is a superset of the ARMv4 ISA with additional support for the Thumb 16-bit compressed instruction set. MMU Performance and Code Density The ARM922T macrocell implements an enhanced ARMv4 MMU to provide translation and access permission checks for the instruction and data address ports of the ARM9TDMI core. The ARM9TDMI core executes two instruction sets The MMU features are: • • • • • • • • • Standard ARMv4 MMU mapping sizes, domains, and access protection scheme Mapping sizes are 1 MB sections, 64 KB large pages, 4 KB small pages, and new 1KB tiny pages Access permissions for sections Access permissions for large pages and small pages can be specified separately for each quarter of the page (subpages) Access permissions for tiny pages 16 domains implemented in hardware 64-entry instruction Translation-Lookaside-Buffer (TLB) and 64-entry data TLB Hardware page table walks Round-robin replacement algorithm (also called cyclic) • 32-bit ARM instruction set • 16-bit Thumb instruction set The ARM instruction set is designed so that a program can achieve maximum performance with the minimum number of instructions. Most ARM9TDMI instructions are executed in a single cycle. The simpler Thumb instruction set offers much increased code density deducing code size and memory requirement. Code can switch between the ARM and Thumb instruction sets on any procedure call. ARM9TDMI Integer Pipeline Stages The integer pipeline consists of five stages to maximize instruction throughput in the ARM9TDMI core: • • • • • Fetch Decode and register read Execute shift and ALU operation, or address calculate, or multiply Memory access and multiply Write register © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 19 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential By using a five-stage pipeline, the ARM922T delivers a throughput approaching one instruction per cycle. Registers The ARM9TDMI processor core consists of a 32-bit datapath and associated conrol logic. This datapath contains 31 generalpurpose registers, coupled to a full shifter, Arithmetic Logic Unit, and a multiplier. At any one time 16 registers are visible to the user. The remainder are mode-specific replacement registers (banked registers) used to speed up execution processing, and make nested exceptions possible. Register 15 is the Program Counter (PC) that can be used in all instructions to reference data relative to the current instruction. R14 holds the return address after a subroutine call. R13 is used (by software convention) as a stack pointer. Exeption Types/Modes The ARM9TDMI core supports five types of exception, and a privileged processing mode for each type. The types of exceptions are: • • • Fast interrupt (FIQ) Normal interrupt (IRQ) Memory aborts (used to implement memory protection or virtual memory) • Attempted execution of an undefined instruction • Software interrupts (SWIs) All exceptions have banked registers for R14 and R13. After an exception, R14 holds the return address for exception processing. This address is used both to return after the exception is processed and to address the instruction that caused the exception. R13 is banked across exception modes to provide each exception handler with a private stack pointer. The fast interrupt mode also banks registers 8 to 12 so that interrupt processing can begin without the need to save or restore these registers. A seventh processing mode, System mode, uses the User mode registers. System mode runs tasks that require a privileged processor mode and enables them to invoke all classes of exceptions. Status Registers All other processor states are held in status registers. The current operating processor status is in the Current Program Status Register (CPSR). The CPSR holds: • • Four ALU flags (Negative, Zero, Carry, Overflow) An interrupt disable bit for each of the IRQ and FIQ interrupts • A bit to indicate ARM or Thumb execution state • Five bits to encode the current processor mode All five exception modes also have a Saved Program Status Register (SPSR) that holds the CPSR of the task immediately before the exception occurred. Conditional Execution All ARM instructions can be executed conditionally and can optionally update the four condition code flags (Negative, Zero, Carry, and Overflow) according to their result. Fifteen conditions are implemented. Classes of Instructions The ARM and Thumb instruction sets can be divided into four broad classes of instruction: • • • • Data processing instructions Load and store instructions Branch instructions Coprocessor instructions Data Processing Instructions The data processing instructions operate on data held in generalpurpose registers. Of the two source operands, one is always a register. The other has two basic forms: • An immediate value • A register value optionally shifted If the operand is a shifted register, the shift can be an immediate value or the value of another register. Four types of shift can be specified. Most data processing instructions can perform a shift followed by a logical or arithmetic operation. There are two classes of multiply instructions: • Normal, 32 bit result • Long, 64 bi resut variants. Both types of multiply instruction can optionally perform an accumulate operation Load and Store Instructions There are two main types of laod and store instructions: • Load or store the value of a single register • Load or store multiple register values Load and store single register instructions can transfer a 32-bit word, a 16-bit halfword, or an 8-bit byte between memory and a register. Byte and halfword loads can be automatically zero extended or sign extended as they are loaded. These instructions have three primary addressing modes: • Offset • Pre-indexed • Post-indexed The address is formed by adding an immediate, or register-based, positive, or negative offset to a base register. Register-based offsets can also be scaled with shift operations. Pre-indexed and post-indexed addressing modes update the base registers with the base plus offset calculation. As the PC is a general-purpose register, a 32-bit balue can be loaded directly into the PC to perform a jump to any address in the 4GB memory space. Load and store multiple instructions perform a block transfer of any number of the general purpose registers to, or from, memory. Four addressing modes are provided: • Pre-increment addressing • Post-increment addressing • Pre-decrement addressing • Post-decrement addressing The base address is specified by a register value (that can be optionally updated after the transfer). As the subroutine return address and the PC values are in general-purpose registers, very efficient subroutine calls can be constructed. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 20 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Branch Instructions As well as letting data processing or load instructions change control flow (by writing the PC) a standard branch instruction is provided with 24-bit signed offset, providing for forward and backward branches of up to 32 MB. A branch with link (BL) instruction enables efficient subroutine calls. BL preserves the address of the instruction after the branch in R14 (Link register or LR). This lets a move instruction put the LR in to the PC and return to the instruction after the branch. The branch and exchange (BX) instruction switches between ARM and Thumb instruction sets with the return address optionally preserving the operating mode of the calling subroutine. Coprocessor Instructions There are three types of coprocessor instructions: • • • Coprocessor data processing instructions Coprocessor register transfer instructions Coprocessor data transfer instructions 7.1.5 JTAG Interface The ARM933T debug interface is based on IEEE Std. 1149.1- 1990, standard test access port. The ARM922T contains hardware extensions for advanced debugging features. These are intended to ease the development of application software. The debug extensions allow the core to be stopped by one of the following: • A given instruction fetch (breakpoint) • A data access (watchpoint) • Asynchronously by a debug request When this happens, the ARM922T is said to be in debug state. At this point, you can examine the internal state of the core and the external state of the system. When examination is complete, you can restore the core and system state and resume program execution. Normally, all control for debugging is done by running a debugger software (ARM AXD or ARM Realview Debugger) on a debug host PC. Connection to the chip is done by an ARM Multi-ICE interface, which connects either to the parallel port or the USB port of the debug host PC. The connection to the multi-ICE interface is done via a 20 way connector and ribbon cable. Following diagram shows the signals connections of the AS3525 to this ICE connector. Figure 6 Interface connector to multi-ICE © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 21 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.1.6 Boot Concept It can be selected if the system should boot either using the internal ROM (internal boot loader) or an external ROM/Flash (connected to the MPMC interface). XPC[0] is read within global chip reset to do the selection of either internal or external boot. Table 11 Boot definitions for internal/external boot selection XPC[0] 1 0 Booting Option Internal ROM External ROM/Flash 7.1.6.1 Internal Bootloader Version C22 Within the internal ROM boot loader several options for booting can be selected: • • • • • • SSP IF - SPI master for ST serial flash types SSP IF - SPI slave NandFlash Debug UART diagnostics IDE boot: direct boot from harddisk USB boot promer. In the case that a USB connection is present and either an update button is pressed or there is no bootable device, the USB promer is started (see Figure 7 Boot decision between normal boot and USB boot promer” for details). The USB boot promer allows update of the firmware by using an USB mass storage class device. This update can be used either for initial programming (factory programming) or as mechanism for an in-field firmware update. All boot loader options of the internal bootloader are configured by XPC[3:1] pins. External pull-up or pull-down resistors should be used to configure the boot options. Table 12 Boot definitions Chip version C22 XPC[3:1] Boot Device 0 1 2 3 4 5 6 7 SPI master ST M25Pxx serial Nor Flash SPI master Atmel AT45DB011B serial Nor Flash SPI slave NandFlash IDE reserved for developers mode UART / Command Line Interface without diagnostics UART / Command Line Interface with diagnostics 000 001 010 011 100 101 110 111 The update button is located between xpa[4] and xpa[0]. Within the key scan routine, xpa[4] is driven shortly to each logic level “0” and “1” and the value of xpa[0] is read back to sense a keypress of the update button. For the USB promer, it is necessary that frequency settings defining the quarz crystal frequency are defined by the pins xpa[6:4]. For details refer to “Table 13 USB promer frequency settings”. These settings are read at the beginning in the initialisation routine of the bootloader. Table 13 USB promer frequency settings XPA[6:4] USB promer frequency settings 000 001 010 011 100 others 24 MHz 20 MHz 13 MHz 12 MHz 10 MHz reserved / defaults to 24 MHz © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 22 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Figure 7 Boot decision between normal boot and USB boot promer © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 23 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2 AHB Peripheral Blocks ARM AHB ("advanced high-performance bus") is the new generation of AMBA bus, which is intended to address the requirements of highperformance synthesizable designs. AMBA AHB implements the features required for high performance, high clock frequency systems including: • • • • • • burst transfers split transactions single cycle bus master handover non-tristate implementation 32 bit bus width the clock frequency of the AHB can set by software up to 65MHz 7.2.1 2.5 MBIT RAM Main Memory The memory subsystem consists of a RAM part and a ROM part. Within the RAM memory subsystem, following functions are included: • • 1-TRAM controller with AHB bus slave interface 1-TRAM memory macros 7.2.1.1 1-TRAM Controller The 1T RAM Controller is a slave interface connected to the AMBA AHB bus. • • • • slave AHB interface supports byte(8 bit), half-word(16 bit) and word(32 bit) read/write accesses 128-bit Line Buffer as temporary storage to reduce the number of memory accesses and optimise power consumption controls 5TSMC 1T-RAM instances 7.2.1.2 On-Chip 1T-RAM macro blocks TSMC Emb1tRAM™ technology is a special kind of DRAM, which is implemented in a logic CMOS process. This innovative concept and design guarantees lowest power, high density, high performance and high yield advantages. ECC (Error Correction Code) technique is applied in the macro to dynamically correct errors caused by hard defects or soft errors. No fuses are needed because the conventional redundancy scheme is replaced with ECC design in the macro. The macro can be operated at clock rate from 20 MHz up to maximum AHB bus clock frequency in flow through random access mode. In the product, one idle cycle for refresh is needed in every 32 clock cycles. Total 5 macros with organisation of 4Kx128 = 64 KByte each are implemented. For the refresh, one master macro is generating the refresh clock (T1F4Kx128_PIFE) and four macros are connected serially in slave mode to the refresh clock (T1F4Kx128PIFES). Features • 20 Mhz to 65 Mhz operation speed • Flow through random access • Built-in error correction (ECC) • 128-bit wide data bus • Separated data in/out bus • SRAM-style interface operation • Built-in refresh controller with refresh clock generator © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 24 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.2 On-Chip ROM 7.2.2.1 ROM Controller The ROM controller implements the AHB slave interface for accessing the ROM. The ROM controller generates OK response for all reads and error response for all writes. Access width is always 32 bits. 7.2.2.2 1MBIT ROM 128 KByte of on-chip mask-programmable ROM are included. The ROM is metal mask programmable by a single mask change (VIA2). The ROM contains the following firmware package • Boot loader 7.2.3 VIC – Vectored Interrupt Controller The ARM PrimeCell™ PL190 “vectored interrupt controller” is included in the AHB system. 7.2.3.1 • • • • • • • • • • • • Features AMBA specification Rev 2.0 compliant support for 32 standard interrupts support for 16 vectored interrupts hardware interrupt priority IRQ and FIQ generation AHB mapped for fast interrupt response software interrupt generation test registers raw interrupt status interrupt request status interrupt masking privileged mode supportBlock Diagram Figure 8 VIC Block Diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 25 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.3.2 VIC Interrupt Sources Table 14 VIC Interrupt Sources IRQ Source 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Module Watchdog Timer 1 Timer 2 USB DMAC Nand Flash IDE MCI INTR0 MCI INTR1 AUDIO IRQ SSP I2C MS I2C Audio I2SIN I2SOUT UART IRQ Source 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 Module GPIO4 (XPD) CGU Memory Stick DBOP GPIO1 (XPA) GPIO2 (XPB) GPIO3 (XPC) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 26 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.4 SMDMAC - Single master DMAC The ARM PrimeCell™ PL081 “SMDMAC single master DMA controller” is included in the AHB system. • • • • • • • • • AMBA specification Rev 2.0 compliant two DMA channels. Each channel can support a unidirectional transfer provides 16 peripheral DMA request lines single DMA and burst DMA request signals. Each peripheral connected to the PrimeCell™ SMDMAC can assert either a burst DMA request or a single DMA request. The DMA burst size is set by programming the PrimeCell™ SMDMAC Memory-to-Memory, memory-to-peripheral, peripheral-to-memory and peripheral-to-peripheral transfers. Scatter or gather DMA is supported through the use of linked lists. This means that the source and destination areas do not need to occupy contiguous areas of memory Hardware DMA channel priority. Each DMA channel has a specific hardware priority. DMA channel 0 has the highest priority and channel 1 has the lowest priority. If requests from two channels become active at the same time the channel with the highest priority is serviced first. AHB slave DMA programming interface. The PrimeCell™ SMDMAC is programmed by writing to the DMA control registers over the AHB slave interface One AHB bus master for transferring data. This interface is used to transfer data when a DMA request goes active. Figure 9 SMDMAC Block Diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 27 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.4.1 Table 15 DMAC Registers DMAC Registers Register Name DMAC_IntStatus DMAC_IntTCStatus DMAC_IntTCClear DMAC_IntErrorStatus DMAC_IntErrorClear DMAC_RawIntTCStatus DMAC_RawIntErrorStatus DMAC_SoftBReq DMAC_SoftSReq DMAC_SoftLBReq DMAC_SoftSBReq DMAC_Configuration DMAC_Sync DMAC_C0SrcAddr DMAC_C0DestAddr DMAC_C0LLI DMAC_C0Control DMAC_C0Configuration DMAC_C1SrcAddr DMAC_C1DestAddr DMAC_C1LLI DMAC_C1Control DMAC_C1Configuration DMAC_PeripheralId0 DMAC_PeripheralId1 DMAC_PeripheralId2 DMAC_PeripheralId3 DMAC_CellId0 DMAC_CellId1 DMAC_CellId2 DMAC_CellId3 Base Address AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE AS3525_DMAC_BASE Offset 0x000 0x004 0x008 0x00C 0x010 0x014 0x018 0x020 0x024 0x028 0x02C 0x030 0x034 0x100 0x104 0x108 0x10C 0x110 0x120 0x124 0x128 0x12C 0x130 0xFE0 0xFE4 0xFE8 0xFEC 0xFF0 0xFF4 0xFF8 0xFFC Note Interrupt status register Interrupt terminal count status register Interrupt terminal count clear register Interrupt error status register Interrupt error clear register Raw interrupt terminal count status register Raw interrupt error status register Software burst request register Software single request register Software last burst request register Software last single request register Configuration register Synchronisation register Channel 0 source address Channel 0 destination address Channel 0 linked list item register Channel 0 control register Channel 0 configuration register Channel 1 source address Channel 1 destination address Channel 1 linked list item register Channel 1 control register Channel 1 configuration register peripheral ID0 register peripheral ID1 register peripheral ID2 register peripheral ID3 register peripheral cell ID0 register peripheral cell ID1 register peripheral cell ID2 register peripheral cell ID3 register © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 28 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.5 Multi Port Memory Controller (MPMC) The MPMC block is integrated into the AMBA system through AHB slave port. The PrimeCell™ MPMC offers: • AMBA 32-bit AHB compliance. • Dynamic memory interface support including SDRAM and JEDEC low-power SDRAM • Asynchronous static memory device support including RAM, ROM, and Flash, with or without asynchronous page mode. • Low transaction latency. • Read and write buffers to reduce latency and to improve performance. • Single AHB interface for accessing external memory. • 8-bit and 16-bit wide static memory support. • 16-bit wide chip select SDRAM memory support. • Static memory features include: • asynchronous page mode read • programmable wait states • bus turnaround delay • output enable, and write enable delays • extended wait • Two chip selects for synchronous memory and two chip selects for static memory devices. • Software controllable HCLK to MPMCCLKOUT ratio. • Power-saving modes dynamically control SDRAM MPMCCKEOUT and MPMCCLKOUT. • Dynamic memory self-refresh mode supported by software. • Controller supports 2K, 4K, and 8K row address synchronous memory parts. That is typical 512MB, 256MB, 128MB, and 16Mb parts, with 8, 16 bits per device. • Two reset domains enable dynamic memory contents to be preserved over a soft reset. • A separate AHB interface to program the MPMC. This enables the PrimeCell™ MPMC registers to be situated in memory with other system peripheral registers. • Locked AHB transactions supported. • Support for all AHB burst types. Figure 10 Multi Port Memory Controller Block Diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 29 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.6 IDE Interface Note: The IDE interface is only available on AS3525-A, not for AS3525-B because some of the IDE PINs are not bonded within the AS3525-B package variant. The IDE host interface core provides an efficient and easy-to-use interface to IDE and ATAPI devices. The core implements programmable I/O, Multi-word DMA, and Ultra ATA-33, -66, -100 and -133 modes of operation and supports up to two devices. The core interface to the system-on-chip provides PIO access and DMA capability to optimise data transfers to and from the IDE devices. For ease of integration, this interface includes a register set compatible with the Intel chip set, including a descriptor-based scatter-gather DMA core. This core is compatible with ATA-4 with Ultra ATA33, -66, -100 and -133 extensions. Single-word DMA is not supported. The licensed SpeedSelectTM technology allows the core to be reconfigured to support any timing mode for PIO, MultiWord DMA, and Ultra ATA transfers (-33, -66, -100 or -133) while running at any clock frequency. Interface to the host processor is the AMBA AHB bus architecture. There are two AHB interfaces on the core: an AHB master and an AHB slave. 7.2.6.1 AHB Master Interface The AHB Master implements a subset of the AHB protocol. The following features are supported: • Single transfer, unspecified-length, 4-beat incrementing and optionally 8-beat incrementing bursts (HBURST will be ‘000’, ‘001’, ‘011’, or optionally ‘101’) • Accesses that cross a 1kB boundary will be unspecified-length incrementing (HBURST will be ‘001’) • 16-bit and 32-bit transfers only (HSIZE will only be ‘001’ or ‘010’) • BUSY cycles are not issued (HTRANS will not be ‘01’) • HPROT is not implemented • OKAY, SPLIT and RETRY responses accepted (HRESP may be ‘00’, ‘10’ or ’11’) • HLOCK asserted during fixed-length bursts • The AHB master may be granted by default 7.2.6.2 AHB Slave Interface The AHB Slave implements a subset of the AHB protocol. The following features are supported: • Non-burst only (HBURST must be ‘000’) • 8-, 16-, or 32-bit transfers only (HSIZE must be ‘000’, ‘001’ or ‘010’) • No advantage is gained by issuing a SEQ cycle over a NONSEQ cycle (HTRANS values of ‘10’ and ‘11’ are interpreted identically) • HPROT is ignored • HRESP is ‘00’ (OKAY) • HREADY is issued no sooner than 2 clock cycles after a valid SEQ or NONSEQ cycle • The AHB slave may be selected by default © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 30 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.6.3 IDE Block diagram Figure 11 IDE Block Diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 31 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.6.4 IDE Interface Registers Table 16 IDE Interface Registers Register Name IdeReg_BMICP IdeReg_BMISP IdeReg_BMIDTPP_LO IdeReg_BMIDTPP_HI IdeReg_IDETIMP_LO IdeReg_IDETIMP_HI IdeReg_IDETIMS_LO IdeReg_IDETIMS_HI IdeReg_SIDETIM IdeReg_SLEWCTL_LO IdeReg_SLEWCTL_HI IdeReg_IDESTAT IdeReg_UDMACTL IdeReg_UDMATIM_LO IdeReg_UDMATIM_HI IdeReg_MISCCTL IdeReg_REGSTB IdeReg_REGRCVR IdeReg_DATSTB IdeReg_DATRCVR IdeReg_DMASTB IdeReg_DMARCVR IdeReg_UDMASTB IdeReg_UDMATRP IdeReg_UDMATENV IdeReg_IORDYTMP IdeReg_IORDYTMS IdeTaskF_DATA IdeTaskF_ERR_FEAT IdeTaskF_SECT_CNT IdeTaskF_SECT_NUM IdeTaskF_CYL_LO IdeTaskF_CYL_HI IdeTaskF_DEV_HEAD IdeTaskF_STAT_CMD IdeTaskF_ALT_STAT_DEV_CTRL IdeTaskF_DEV_ADDR Base Address AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE AS3525_CF_IDE_BASE Offset 0x00 0x02 0x04 0x06 0x40 0x41 0x42 0x43 0x44 0x45 0x46 0x47 0x48 0x4A 0x4B 0x50 0x54 0x58 0x5C 0x60 0x64 0x68 0x6C 0x70 0x74 0x78 0x7C 0x1F0 0x1F1 0x1F2 0x1F3 0x1F4 0x1F5 0x1F6 0x1F7 0x3F6 0x3F7 Note primary channel bus master command primary channel bus master status primary channel bus master table pointer primary channel timing register secondary channel timing register slave IDE timing register slew rate control register IDE status register ultra DMA control register ultra DMA timing register miscellaneous control register task file register strobe timing register task file register recovery timing register data register PIO strobe timing register data register PIO recovery timing register DMA strobe timing register DMA recovery timing register ultra DMA strobe timing register ultra DMA ready-to-stop timing register ultra DMA timing envelope register primary IO ready timer configuration reg secondary IO ready timer configuration reg © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 32 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.7 USB 2.0 HS OTG interface The USB 2.0 on-chip interface includes the USB 2.0 On-The-Go Physical Interface and the HS OTG controller. Figure 12 USB 2.0 Interface 7.2.7.1 HS OTG controller subsystem The Synopsys HS OTG subsystem is a configurable design. The HS OTG subsystem is fully compliant with the On-TheGo supplement to the USB 2.0 specification, Revision 1.0a. The subsystem supports high speed (480-Mbps) and fullspeed transfers. It is designed to interface to the AMBA AHB bus, shielding the application from the complexities of the HS OTG subsystem-native protocols and simplifying the system interface. The OTG subsystem can be configured using application software as follows: • • • OTG dual-role device (DRD) OTG device only OTG mini host only • • • USB High-Speed (HS) device USB HS mini host USB Full-Speed (FS) device The HS OTG subsystem has the following interfaces • • • • • the UTMI+, which connect the on-chip PHY to the HS OTG core the AHB slave interface, which provides the microcontroller with read and write access to the core's control and status register (CSRs) the AHB master interface, which enables the core to act as a master on the AHB to transfer data to and from the core's DMA controller the descriptor prefetch buffer RAM interface, which connects to an single-port RAM for DMA descriptor prefetch buffer storage the data RAM interface, which connects to and dual-port RAM (FIFO memory) for transaction data storage General features • • • • handles all clock synchronisation within the core uses a descriptor prefetch buffer for optimal AHB use in host mode supports adaptive buffering for dynamic FIFO memory allocation, avoiding gaps in RAM utilisation SOFs are supported in high/full speed modes • • • includes built-in DMA includes hardware transaction scheduling for enhanced performance supports memory mapped address space for the CSRs USB 2.0 supported features • • • • supports up to 15 configurations in Device mode • each configuration supports 15 interfaces • each interface handles up to 15 alternate settings supports session request protocol (SRP) supports session request protocol (SRP) supports Host Negotiation Protocol (HNP) recovers clock and data from the USB • • • supports a generic root hub includes auto ping/split completion capabilities complies with UTMI+ level 3 interface Implemented Controller configurations are: • • configured with 4 host channels and 3 bidirectional- plus 1 in-endpoints in device mode dynamic alternate configuration selection (for different bandwidths of isochronous endpoints) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 33 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Figure 13 USB 2.0 OTG Controller Block Diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 34 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.7.2 • • • • • • • • USB 2.0 OTG PHY Complete PHY for USB2.0 On-The-Go USB 2.0 UTMI+ specification compliant Supports high speed (480 Mbit/s), full speed (12 Mbit/s) and low speed (1.5 Mbit/s) data transmission Supports OT supplement features: VBUS state detecting SRP request by “data-line pulsing” method Low jitter clock from either on-chip PLL (48MHz) or optional additional crystal (12MHz, 24MHz or 48MHz) which is available with the 224 pin package, only 16 bit parallel datain/out interface Typical current consumption on vdda33c and vdd33t: • 12 mA in FS RX mode • 30 mA in FS TX mode • 30 mA in HS RX mode • 40 mA in HS TX mode • < 100 uA in suspend mode Rext = 3.4kOhm (+/- 1%) must be connected between pads “rext” and “vssa33c” to set the bias current. 7.2.7.3 USB 2.0 OTG Interface Registers Table 17 USB Interface Registers Register Name USB_IEP0_CTRL USB_IEP0_STS USB_IEP0_TXFSIZE USB_IEP0_MPS USB_IEP0_DESC_PTR USB_IEP0_STS_MASK USB_IEP1_CTRL USB_IEP1_STS USB_IEP1_TXFSIZE USB_IEP1_MPS USB_IEP1_DESC_PTR USB_IEP1_STS_MASK USB_IEP2_CTRL USB_IEP2_STS USB_IEP2_TXFSIZE USB_IEP2_MPS USB_IEP2_DESC_PTR USB_IEP2_STS_MASK USB_IEP3_CTRL USB_IEP3_STS USB_IEP3_TXFSIZE USB_IEP3_MPS USB_IEP3_DESC_PTR USB_IEP3_STS_MASK USB_OEP0_CTRL USB_OEP0_STS USB_OEP0_RXFR USB_OEP0_MPS USB_OEP0_SUP_PTR USB_OEP0_DESC_PTR USB_OEP0_STS_MASK USB_OEP1_CTRL USB_OEP1_STS USB_OEP1_RXFR Base Address AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE Offset 0x00000 0x00004 0x00008 0x0000c 0x00014 0x00018 0x00020 0x00024 0x00028 0x0002c 0x00034 0x00038 0x00040 0x00044 0x00048 0x0004c 0x00054 0x00058 0x00060 0x00064 0x00068 0x0006c 0x00074 0x00078 0x00200 0x00204 0x00208 0x0020c 0x00210 0x00214 0x00218 0x00220 0x00224 0x00228 Note Control Register Status Register TxFIFO Size Maximum Packet Size Data Descriptor Pointer Status Mask Register Control Register Status Register TxFIFO Size Maximum Packet Size Data Descriptor Pointer Status Mask Register Control Register Status Register TxFIFO Size Maximum Packet Size Data Descriptor Pointer Status Mask Register Control Register Status Register TxFIFO Size Maximum Packet Size Data Descriptor Pointer Status Mask Register Control Status Register Rx Packet Frame Number Register RxFIFO Size/Maximum Packet Size Setup buffer Pointer Register Data Descriptor Pointer Status Mask Register Control Register Status Register Rx Packet Frame Number Register © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 35 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Register Name USB_OEP1_MPS USB_OEP1_SUP_PTR USB_OEP1_DESC_PTR USB_OEP1_STS_MASK USB_OEP2_CTRL USB_OEP2_STS USB_OEP2_RXFR USB_OEP2_MPS USB_OEP2_SUP_PTR USB_OEP2_DESC_PTR USB_OEP2_STS_MASK USB_OEP3_CTRL USB_OEP3_STS USB_OEP3_RXFR USB_OEP3_MPS USB_OEP3_SUP_PTR USB_OEP3_DESC_PTR USB_OEP3_STS_MASK USB_DEV_CFG USB_DEV_CTRL USB_DEV_STS USB_DEV_INTR USB_DEV_INTR_MASK USB_DEV_EP_INTR USB_DEV_EP_INTR_MASK USB_PHY_EP0_INFO USB_PHY_EP1_INFO USB_PHY_EP2_INFO USB_PHY_EP3_INFO USB_PHY_EP4_INFO USB_PHY_EP5_INFO USB_HOST_CH0_SPLT USB_HOST_CH0_STS USB_HOST_CH0_TXFSIZE USB_HOST_CH0_REQ USB_HOST_CH0_PER_INFO Base Address AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE Offset 0x0022c 0x00230 0x00234 0x00238 0x00240 0x00244 0x00248 0x0024c 0x00250 0x00254 0x00258 0x00260 0x00264 0x00268 0x0026c 0x00270 0x00274 0x00278 0x00400 0x00404 0x00408 0x0040c 0x00410 0x00414 0x00418 0x00504 0x00508 0x0050c 0x00510 0x00514 0x00518 0x01000 0x01004 0x01008 0x0100c 0x01010 USB_HOST_CH0_DESC_PTR USB_HOST_CH0_STS_MASK USB_HOST_CH1_SPLT USB_HOST_CH1_STS USB_HOST_CH1_TXFSIZE USB_HOST_CH1_REQ USB_HOST_CH1_PER_INFO AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE 0x01014 0x01018 0x01020 0x01024 0x01028 0x0102c 0x01030 USB_HOST_CH1_DESC_PTR USB_HOST_CH1_STS_MASK USB_HOST_CH2_SPLT USB_HOST_CH2_STS USB_HOST_CH2_TXFSIZE USB_HOST_CH2_REQ USB_HOST_CH2_PER_INFO AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE 0x01034 0x01038 0x01040 0x01044 0x01048 0x0104c 0x01050 Note RxFIFO Size/Maximum Packet Size Setup buffer Pointer Register Data Descriptor Pointer Status Mask Register Control Register Status Register Rx Packet Frame Number Register RxFIFO Size/Maximum Packet Size Setup buffer Pointer Register Data Descriptor Pointer Status Mask Register Control Register Status Register Rx Packet Frame Number Register RxFIFO Size/Maximum Packet Size Setup buffer Pointer Register Data Descriptor Pointer Status Mask Register Device Configuration Register Device Control Register Device Status Register Device Interrupt Register Device Interrupt Mask Register Device Endpoint Interrupt Device Endpoint Interrupt Mask Information Register Information Register Information Register Information Register Information Register Information Register Split Information Register Status Register TxFIFO Register Request Register Periodic/Split Transaction Information Register Data Descriptor Pointer Status Mask Register Split Information Register Status Register TxFIFO Register Request Register Periodic/Split Transaction Information Register Data Descriptor Pointer Status Mask Register Split Information Register Status Register TxFIFO Register Request Register Periodic/Split Transaction Information © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 36 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Register Name Base Address Offset USB_HOST_CH2_DESC_PTR USB_HOST_CH2_STS_MASK USB_HOST_CH3_SPLT USB_HOST_CH3_STS USB_HOST_CH3_TXFSIZE USB_HOST_CH3_REQ USB_HOST_CH3_PER_INFO AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE 0x01054 0x01058 0x01060 0x01064 0x01068 0x0106c 0x01070 USB_HOST_CH3_DESC_PTR USB_HOST_CH3_STS_MASK USB_HOST_CFG USB_HOST_CTRL USB_HOST_INTR USB_HOST_INTR_MASK USB_HOST_CH_INTR USB_HOST_CH_INTR_MASK USB_HOST_FRAME_INT USB_HOST_FRAME_REM USB_HOST_FRAME_NUM USB_HOST_PORT0_CTRL_STS USB_OTG_CSR USB_I2C_CSR USB_GPIO_CSR AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE 0x01074 0x01078 0x01400 0x01404 0x0140c 0x01410 0x01414 0x01418 0x0141c 0x01420 0x01424 0x01500 0x02000 0x02004 0x02008 USB_SNPSID_CSR USB_USERID_CSR USB_USER_CONF1 USB_USER_CONF2 USB_USER_CONF3 USB_USER_CONF4 USB_USER_CONF5 AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE AS3525_USB_BASE 0x0200c 0x02010 0x02014 0x02018 0x0201c 0x02020 0x02024 Note Register Data Descriptor Pointer Status Mask Register Split Information Register Status Register TxFIFO Register Request Register Periodic/Split Transaction Information Register Data Descriptor Pointer Status Mask Register Host Configuration Register Host Control Register Host Interrupt Register Host Interrupt Mask Register Host Channel Interrupt Register Host Channel Interrupt Mask Register Host Frame Interval Register Host Frame Remaining Register Host Frame Number Register Host Port and Status Register OTG Control and Status Register I2C Access Register General Purpose Input/Output Register Synopsys ID Register User ID Register User Config1 Register User Config2 Register User Config3 Register User Config4 Register User Config5 Register © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 37 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.8 Memory Stick / Memory Stick Pro Interface The Sony memory stick interface is an AHB bus slave device. This interface conforms to following standards: • Memory Stick Standard Format Specifications version 1.4-00 • Memory Stick PRO Format Specifications version 1.00-01 7.2.8.1 Block Diagram The memory stick interface contains two main blocks, the ICON and the host controller. Figure 14 SONY memory stick interface block diagram 7.2.8.2 I-CON This IP is Memory Stick / Memory Stick PRO Host Controller automatic control IP with a 32-bit CPU interface. This IP automatically controls the series of TPC-based communication with the Memory Stick in place of the CPU, and aims to reduce the burden on the Host CPU. The contents of communication with the Memory Stick are designated in this IP by micro codes. Features • • • • • • 32-bit CPU interface Inside controller specified by microcodes Buffer for two-way data transmission loaded (256 byte x 2) 32/16 bit access available DMA support General-purpose data transmit/receive FIFO (12 Bytes) 7.2.8.3 Host Controller Features • • • • • • Memory Stick and Memory Stick PRO support FiFo memory (64 bits × 4) for two-way data transmission Built-in CRC circuit Memory Stick serial clock (Serial: 20 MHz (max.), Parallel: 40 MHz (max.)) DMA support 16/32/64-bit access possible © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 38 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.2.8.4 Functional description Communication with the Memory Stick The communication protocol with the Memory Stick is started by write from the CPU to the command register. When the protocol finishes, the CPU is notified that the protocol has ended by an interrupt request. Data transfer request When the protocol is started and enters the data transfer state, data is requested by issuing a DMA transfer request or an interrupt request to the CPU. Data can also be requested to an external memory. Memory Stick communication time out The RDY time out time when the handshake state (read protocol: BS2, write protocol: BS3) is established in communication with the Memory Stick can be designated as the number of Memory Stick transfer clocks. When a time out occurs, the CPU is notified that the protocol has ended due to a time out error by an interrupt request. CRC off CRC off can be set as a test mode. When CRC off is set, CRC is not added to the data transmitted to the Memory Stick. PAD cells The connections to the MemoryStick Interface are shared with the General Purpose I/O port-D (GPIO xpd[0:7]). Figure 15 external memory stick connection © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 39 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3 APB Peripheral Block 7.3.1 Timers The Dual Input Timers module is an APB slave that provides access to two interrupt-generating, programmable 32-bit free-running decrementing counters (FRCs). The system clock (PCLK) is used to control the programmable registers, and the second clock input is used to drive the counter, enabling the counters to run from a much slower clock than the system clock. This input clock of the counters (TIMCLK) is connected to a clock derived (divided by 16) from the main clock (clk_main) signal. That clock clk_main is always running and is coming from the internal or external oscillator (set by clk_sel pad). 7.3.1.1 Timer modes • • • Free-running mode: the counter wraps after zero and continues at the maximum value. This is the default mode. Periodic mode: reload of original value after wrapping past zero. One-shot mode - interrupt is generated once, counter halts after reaching zero Figure 16 Timer Block Diagram Each timer has an identical set of registers shown in table Table 18. The operation of each timer is identical. The timer is loaded by writing to the load register and, if enabled, counts down to zero. When a counter is already running, writing to the load register will cause the counter to immediately restart at the new value. Writing to the background load value has no effect on the current count. The counter continues to decrement to zero, and then recommences from the new load value (if in periodic mode, and one shot mode is not selected). When zero is reached, an interrupt is generated. The interrupt can be cleared by writing to the clear register. If One Shot Mode is selected, the counter halts on reaching zero One Shot Mode is deselected, or a new load value is written. Otherwise, after reaching a zero count, if the timer is operating in free-running mode it continues to decrement from its maximum value. If periodic timer mode is selected, the timer reloads the count value from the load register and continues to decrement. In this mode the counter effectively generates a periodic interrupt. The mode is selected by a bit in the timer control register. At any point, the current counter value can be read from the value register. The counter is enabled by a bit in the control register. At reset, the counter is disabled, the interrupt is cleared, and the load register is set to zero. The mode and prescale values are set to free-running, and clock divide of 1 respectively. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 40 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential The timer clock enable is generated by a prescale unit. The enable is then used by the counter to create a clock with a timing of one of the following. • • • The system clock The system clock divided by 16, generated by 4 bits of prescale The system clock divided by 256, generated by a total of 8 bits of prescale Figure 17 - timer prescaler 7.3.1.2 Interrupt generation An interrupt is generated when the full 32-bit counter reaches zero, and is only cleared when the TimerXClear location is written to. A register holds the value until the interrupt is cleared. The most significant carry bit of the counter detects the counter reaching zero. Interrupts can be masked by writing 0 to the interrupt enable bit in the control register. Both the raw interrupt satus (prior to masking) and the final interrupt status (after masking) can be read from status registers. Timer 1 interrupt output is connected to interrupt input line irq1 (VIC input) and Timer 2 interrupt output is connected to interrupt line irq2. 7.3.1.3 Timer Register Descriptions Table 18 – Timer 1 and 2 registers Register Name Timer1Load Timer1Value Timer1Control Timer1IntClr Timer1RIS Timer1MIS Timer1BGLoad Timer2Load Timer2Value Timer2Control Timer2IntClr Timer2RIS Timer2MIS Timer2BGLoad Periheral ID register bits 7:0 Periheral ID register bits 15:8 Periheral ID register bits 23:16 Periheral ID register bits 31:24 Primecell ID register bits 7:0 Primecell ID register bits 15:8 Primecell ID register bits 23:16 Primecell ID register bits 31:24 Base Address AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE AS3525_TIMER_BASE Offset 0x00 0x04 0x08 0x0C 0x10 0x14 0x18 0x20 0x24 0x28 0x2C 0x30 0x34 0x38 0xFE0 0xFE4 0xFE8 0xFEC 0xFF0 0xFF4 0xFF8 0xFFC Note load value for Timer 1 current value for Timer 1 Timer 1 control register Timer 1 interrupt clear Timer 1 raw interrupt status Timer 1 masked interrupt status Timer 1 background load value load value for Timer 2 current value for Timer 2 Timer 2 control register Timer 2 interrupt clear Timer 2 raw interrupt status Timer 2 masked interrupt status Timer 2 background load value Peripheral ID register bits 7:0 Peripheral ID register bits 15:8 Peripheral ID register bits 23:16 Peripheral ID register bits 31:24 Primecell ID register bits 7:0 Primecell ID register bits 15:8 Primecell ID register bits 23:16 Primecell ID register bits 31:24 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 41 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Load register, Timer1Load, Timer2Load This is a 32-bit register containing the value from which the counter is to decrement. This is the value used to reload the counter when periodic mode is enabled, and the current count reaches zero. When this register is written to directly, the current count is immediately reset to the new value at the next rising edge of TIMCLK which is enabled by TIMCLKEN. The value in this register is also overwritten if the TimerXBGLoad register is written to, but the current count is not immediately affected. If values are written to both the timerXLoad and TimerXBGLoad registers before an enabled rising edge on TIMCLK, the following occurs: • On the next enabled TIMCLK edge the value written to the TimerXLoad value replaces the current count value • Following this, eacht time the counter reaches zero, the current count value is reset to the value written to TimerXBGLoad. Reading from the TimerXLoad register at any time after the two writes have occurred will retrieve the value written to TimerXBGLoad. That is, the value read from TimerXLoad is always the value which will take effect for periodic mode after the next time the counter reaches zero. Current value register, Timer1Value, Timer2Value This register gives the current value of the decrementing counter. Timer control register Table 19 Timer control register Name Base Default Timer1Control, Timer2Control AS3525_TIMER_BASE 0x20 Offset: 0x08, 0x28 Timer Control Register Contains control bits of the PLLA register. Bit 7 Bit Name Timer Enable 0 Default Access R/W 6 Timer Mode 0 R/W 5 Interrupt Enable 1 R/W 4 3:2 RESERVED TimerPre 00 R/W 1 Timer Size 0 R/W 0 OneShotCount 0 R/W Bit Description Enable bit: 0: timer disabled (default) 1: timer enabled Mode bit 0: timer is in free-running mode (default) 1: timer is in periodic mode Interrupt enable bit 0: timer interrupt disabled 1: timer interrupt enabled (default) Reserved bit, do not modify, and ignore on read Prescale bits: 00: no prescale, clock is divided by 1 (default) 01: 4 stages of prescale, clock is divided by 16 10: 8 stages of prescale, clock is divided by 256 11: undefined, do not use Selects 16/32 bit counter operation 0: 16 bit counter (default) 1: 32 bit counter Selects one-shot or wrapping counter mode 0: wrapping mode (default) 1: one-shot mode Interrupt clear register, Timer1IntClr, Timer2IntClr Any write to this register will clear the interrupt output from the counter © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 42 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Raw Interrupt status register, Timer1RIS, Timer2RIS This register indicates the raw interrupt status from the counter. This value is ANDed with the timer interrupt enable bit from the control register to create the masked interrupt, which is passed to the interrupt output pin. Table 20 raw interrupt status register Name Base Timer1RIS, Timer2RIS AS3525_TIMER_BASE Offset: 0x10, 0x30 Bit 0 Bit Name Raw Timer Interrupt Default Timer raw interrupt status register Contains control bits of the PLLA register. Default Access R Bit Description Raw interrupt status from the counter Interrupt status register, TIMERXMIS This register indicates the masked interrupt status from the counter. This value is the logical AND of the raw interrupt status with the timer interrupt enable bit from the control register, and is the same value which is passed to the interrupt output pin. Table 21 interrupt status register Name Base Timer1MIS, Timer2MIS AS3525_TIMER_BASE Offset: 0x10, 0x30 Bit 0 Bit Name Raw Timer Interrupt Default Timer raw interrupt status register Contains control bits of the PLLA register. Default Access R Bit Description Raw interrupt status from the counter Background load register, TimerXBGLoad This is a 32 bit register containing the value from which the counter is to decrement. This is the value used to reload the counter when periodic mode is enabled, and the current count reaches zero. This register privides an alternative method of accessing the TimerXLoad register. The difference is that writes to TimerXBGLoad will not cause the counter immediately to restart from the new value. Reading from this register returns the same value returned from TimerXLoad. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 43 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.2 Watchdog Unit The watchdog unit provides a way of recovering from software crashes. The watchdog clock is used to generate a regular interrupt (WDOGINT), depending on a programmed value. The watchdog monitors the interrupt and asserts a reset signal (WDOGRES) if the interrupt remains unserviced for the entire programmed period. You can enable or disable the watchdog unit as required. Clock reference for the watchdog is PCLK divided by 256. Figure 18 watchdog unit 7.3.2.1 Watchdog register descriptions Table 22 Watchdog Registers Register Name WDT_LOAD WDT_VALUE WDT_CONTROL WDT_INTCLR WDT_RIS WDT_MIS WDT_LOCK WDT_PERIPHID0 WDT_PERIPHID1 WDT_PERIPHID2 WDT_PERIPHID3 WDT_PCELLID0 WDT_PCELLID1 WDT_PCELLID2 WDT_PCELLID3 Base Address AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE AS3525_WDT_BASE Offset 0x00 0x04 0x08 0x0C 0x10 0x14 0xC00 0xFE0 0xFE4 0xFE8 0xFEC 0xFF0 0xFF4 0xFF8 0xFFC Note load register counter current value control register Interrupt clear register Raw interrupt status register Masked interrupt status register Lock register Watchdog peripheral ID 0 register Watchdog peripheral ID 1 register Watchdog peripheral ID 2 register Watchdog peripheral ID 3 register Watchdog primecell ID 0 register Watchdog primecell ID 1 register Watchdog primecell ID 2 register Watchdog primecell ID 3 register Watchdog load register, WdogLoad This is a 32-bit register containing the value from which the counter is to decrement. When this register is written to, the count is immediately restarted from the new value. The minimum valid value for WdogLoad is one. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 44 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Watchdog control register, WdogControl This is a read/write register that enables the software to control the watchdog unit. Table 23 watchdog control register Name Base Default WdogControl AS3525_WDT_BASE 0x04 Watchdog Control Register Offset: 0x08 Bit 1 Bit Name RESEN 0 Default Access R/W 0 INTEN 0 R/W Bit Description Enable Watchdog reset output (WDOGRES). Acts as a mask for the reset output. 0: disable the reset 1: enable the reset Enable the interrupt event (WDOGINT). 0: disable the counter and interrupt 1: enable the counter and interrupt Watchdog clear interrupt register, WdogIntClr A write of any value to this location clears the watchdog interrupt, and reloads the counter from the value in WdogLoad. Raw interrupt status register, WdogRIS This register indicates the raw interrupt status from the counter. This value is ANDed with the inerrupt enable bit from the control register to create the masked interrupt, which is passed to the interrupt output pin. Table 24 watchdog raw interrupt status register Name Base WdogRIS AS3525_WDT_BASE Watchdog interrupt status register Offset: 0x10 Bit 0 Bit Name Watchdog Interrupt Default Default Access R Bit Description Enabled interrupt status from the counter Interrupt status register, WdogMIS This register indicates the masked interrupt status from the counter. This value is the logical AND of the raw interrupt status with the INTEN bit from the control register, and is the same value which is passed to the interrupt output pin. Name Base WdogMIS AS3525_WDT_BASE Watchdog raw interrupt status register Offset: 0x14 Bit 0 Bit Name Raw Watchdog Interrupt Default Default Access R Bit Description Raw interrupt status from the counter Table 25 watchdog interrupt status register © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 45 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Watchdog lock register, WdogLock Use of this register allows write-access to all other registers to be disabled. This is to prenent rogue software from disabling the watchdog functionality. Writing a value of 0x1ACCE551 will enable write access to all other registers. Writing any other value will disable write accesses. A read from this register will return only the bottom bit: • • 0 indicates that write access is enabled (not locked) 1 indicates that write access is disabled (locked) Table 26 watchdog lock register Name Base Default WdogLock AS3525_WDT_BASE 0x00 Watchdog raw interrupt status register Offset: 0xC00 Bit 31:0 0 Bit Name Enable register writes Register write enable status Default 0 Access W R Bit Description Enable write access to all other registers by writing 0x1ACCE551. Disable write access by writing any other value. 0: write access to all other registers is enabled (default) 1: write access to all other registers is disabled © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 46 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.3 SSP – Synchronous Serial Port The SSP is a master or slave interface that enables synchronous serial communication with slave or master peripherals having one of the following: • a Motorola SPI-compatible interface • a TI synchronous serial interface • a National Semiconductor MicroWire interface In both master and slave configurations the SSP performs • parallel-to-serial conversion on data written to an internal 16-bit wide, 8-location deep transmit FIFO • serial-to-parallel conversion on received data, buffering it in a similar 16-bit wide, 8 location-deep receive FIFO Interrupts are generated to: • request servicing of the transmit and receive FIFO • inform the system that a receive FIFO overrun has occurred • inform the system that data is present in the receive FIFO after an idle period has expired SSP Features: • compliant to AMBA Rev 2.0 • master or slave operation • programmable clock bit rate and prescale • separate receive and transmit memory buffers each 16 bits wide and 8 bits deep • programmable data frame size from 4 to 16 bit • independent masking of receive FIFO, transmit FIFO and receive overrun interrupts • internal loopback testmode available • support for DMA • identification register uniquely identifying the PrimeCell™ itself (support for OS) SPI features: • full-duplex, four wire synchronous transfer • programmable clock polarity and phase MicroWire features: • half duplex transfer using 8 bit control message Texas Instruments SSI features: • full-duplex, four wire synchronous transfer • transmit data PIN tristateable when not transmitting Programmable parameters: • master or slave mode • enabling of operation • frame format • communication baud rate • clock phase and polarity • data width from 4 to 16 bit • interrupt masking © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 47 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Figure 19 Serial Synchronous Port Block Diagram Table 27 SSP Registers Register Name SPI_SSPCR0 SPI_SSPCR1 SPI_SSPRXD SPI_SSPTXD SPI_SSPSR SPI_SSPCPSR SPI_SSPIMSC SPI_SSPIRS SPI_SSPMIS SPI_SSPICR SPI_SSPDMACR Base Address SSP_BASE SSP_BASE SSP_BASE SSP_BASE SSP_BASE SSP_BASE SSP_BASE SSP_BASE SSP_BASE SSP_BASE SSP_BASE Offset 0x00 0x04 0x08 0x08 0x0C 0x10 0x14 0x18 0x1C 0x20 0x24 Note CR0 control register CR1 control register Read Data Register Write Data register SSP status register SSP Pre-scaler register SSP Interrupt Mask and clear register SSP Raw interrupt status register SSP Masked interrupt status register SSP interrupt clear register SSP DMA control register © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 48 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.4 GPIO - General purpose input/output ports The ARM PrimeCell™ PL061 “General Purpose Input/Output” is included in the APB system. • • • • • • compliant to AMBA Rev 2.0 each port has eight individually programmable input/output pins, default to input at reset four ports A, B, C, D are included programmable interrupt generation capability, from a transition or level condition, on any number of PINs hardware control capability of GPIO’s for different system configurations. bit masking in both read and write operations through address lines Figure 20 GPIO Block Diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 49 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.4.1 GPIO register descriptions Table 28: GPIO Registers Register Name GPIO1_DATA GPIO1_DIR GPIO1_IS GPIO1_IBE GPIO1_IEV GPIO1_IE GPIO1_RIS GPIO1_MIS GPIO1_IC GPIO1_AFSEL GPIO2_DATA GPIO2_DIR GPIO2_IS GPIO2_IBE GPIO2_IEV GPIO2_IE GPIO2_RIS GPIO2_MIS GPIO2_IC GPIO2_AFSEL GPIO3_DATA GPIO3_DIR GPIO3_IS GPIO3_IBE GPIO3_IEV GPIO3_IE GPIO3_RIS GPIO3_MIS GPIO3_IC GPIO3_AFSEL GPIO4_DATA GPIO4_DIR GPIO4_IS GPIO4_IBE GPIO4_IEV GPIO4_IE GPIO4_RIS GPIO4_MIS GPIO4_IC GPIO4_AFSEL Base Address AS3525_GPIO1_BASE AS3525_GPIO1_BASE AS3525_GPIO1_BASE AS3525_GPIO1_BASE AS3525_GPIO1_BASE AS3525_GPIO1_BASE AS3525_GPIO1_BASE AS3525_GPIO1_BASE AS3525_GPIO1_BASE AS3525_GPIO1_BASE AS3525_GPIO2_BASE AS3525_GPIO2_BASE AS3525_GPIO2_BASE AS3525_GPIO2_BASE AS3525_GPIO2_BASE AS3525_GPIO2_BASE AS3525_GPIO2_BASE AS3525_GPIO2_BASE AS3525_GPIO2_BASE AS3525_GPIO2_BASE AS3525_GPIO3_BASE AS3525_GPIO3_BASE AS3525_GPIO3_BASE AS3525_GPIO3_BASE AS3525_GPIO3_BASE AS3525_GPIO3_BASE AS3525_GPIO3_BASE AS3525_GPIO3_BASE AS3525_GPIO3_BASE AS3525_GPIO3_BASE AS3525_GPIO4_BASE AS3525_GPIO4_BASE AS3525_GPIO4_BASE AS3525_GPIO4_BASE AS3525_GPIO4_BASE AS3525_GPIO4_BASE AS3525_GPIO4_BASE AS3525_GPIO4_BASE AS3525_GPIO4_BASE AS3525_GPIO4_BASE Offset 0x000 0x400 0x404 0x408 0x40C 0x410 0x414 0x418 0x41C 0x420 0x000 0x400 0x404 0x408 0x40C 0x410 0x414 0x418 0x41C 0x420 0x000 0x400 0x404 0x408 0x40C 0x410 0x414 0x418 0x41C 0x420 0x000 0x400 0x404 0x408 0x40C 0x410 0x414 0x418 0x41C 0x420 GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO Note data register data direction register interrupt sense register interrupt both edges register interrupt event register interrupt mask register raw interrupt status masked interrupt status interrupt clear mode control select data register data direction register interrupt sense register interrupt both edges register interrupt event register interrupt mask register raw interrupt status masked interrupt status interrupt clear mode control select data register data direction register interrupt sense register interrupt both edges register interrupt event register interrupt mask register raw interrupt status masked interrupt status interrupt clear mode control select data register data direction register interrupt sense register interrupt both edges register interrupt event register interrupt mask register raw interrupt status masked interrupt status interrupt clear mode control select © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 50 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential GPIO data register Table 29 GPIO data register Bit 7:0 Name Base Default GPIO1_DATA GPIO2_DATA GPIO3_DATA GPIO4_DATA AS3525_GPIO1_BASE AS3525_GPIO2_BASE AS3525_GPIO3_BASE AS3525_GPIO4_BASE 0xC80B0000 0xC80C0000 0xC80D0000 0xC80E0000 Offset: 0x000 GPIO data register In software control mode (GPIO1_AFSEL,...), values written in this register are transferred onto the GPOUT pins if the respective pins have been configured as outputs through the GPIO1_DIR, .. . So that GPIO bits can be set without affect to other pins in a single write operation, the address bus is used as a mask on read/write operation. The data register covers 256 locations in the address space. The eight address lines used are PADDR[9:2]. During a write, only GPIO1_DATA,... bits corresponding to HIGH address bits are updated. During a read all data bits corresponding to HIGH address bits are read, the other bits are zero. A read from this register returns the last bit value written if the respective pins are configured as output, or it returns the value on the corresponding input GPIN bit when these are configured as inputs. All bits are cleared by a reset. Bit Name GPIO data register Default 00000000 Access RW Bit Description Input data, output data. GPIO data direction register Table 30 GPIO data direction register Name Base Default GPIO1_DIR GPIO2_DIR GPIO3_DIR GPIO4_DIR AS3525_GPIO1_BASE AS3525_GPIO2_BASE AS3525_GPIO3_BASE AS3525_GPIO4_BASE 0xC80B0000 0xC80C0000 0xC80D0000 0xC80E0000 Offset: 0x400 Bit 7:0 Bit Name GPIO data direction register GPIO data direction register Bits set to HIGH configure corresponding pin to be an output. Clearing a bit configures the pin to be input. All bits are cleared by a reset. Default 00000000 Access RW Bit Description 0: pins input 1: pins output © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 51 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential GPIO interrupt sense register Table 31 GPIO interrupt sense register Name Base Default GPIO1_IS GPIO2_IS GPIO3_IS GPIO4_IS AS3525_GPIO1_BASE AS3525_GPIO2_BASE AS3525_GPIO3_BASE AS3525_GPIO4_BASE 0xC80B0000 0xC80C0000 0xC80D0000 0xC80E0000 Offset: 0x404 Bit 7:0 Bit Name GPIO interrupt sense register GPIO interrupt sense register Bits set to HIGH configure the corresponding pins to detect levels. Clearing a bit configures the pin to detect edges. All bits are cleared by a reset. Default 00000000 Access RW Bit Description 0: edge on corresponding pin is detected 1: level on corresponding pin is detected GPIO interrupt both edges register Table 32 GPIO interrupt both edges register Name Base Default GPIO1_IBE GPIO2_IBE GPIO3_IBE GPIO4_IBE AS3525_GPIO1_BASE AS3525_GPIO2_BASE AS3525_GPIO3_BASE AS3525_GPIO4_BASE 0xC80B0000 0xC80C0000 0xC80D0000 0xC80E0000 Offset: 0x408 Bit 7:0 Bit Name GPIO interrupt event register GPIO interrupt both edges register When the corresponding bit in GPIO interrupt sense register (GPIO1_IS, …) is set to detect edges, bits set to HIGH in GPIO interrupt both edges register (GPIO1_IBE, … ) configure the corresponding pin to detect both rising and falling edges, regardless of the corresponding bit in the GPIO interrupt event register (GPIO1_IEV, …). Clearing a bit configures the pin to be controlled by GPIO interrupt event register (GPIO1_IEV, …). All bits are cleared by a reset. Default 00000000 Access RW Bit Description 0: on corresponding pin interrupt generation event is controlled by GPIO interrupt event register (GPIO1_IEV, …). 1: both edges on corresponding pin trigger an interrupt. Single edge determined by corresponding bit in GPIO interrupt event register (GPIO1_IEV, …). © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 52 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential GPIO interrupt event register Table 33 GPIO interrupt event register Name Base Default GPIO1_IEV GPIO2_IEV GPIO3_IEV GPIO4_IEV AS3525_GPIO1_BASE AS3525_GPIO2_BASE AS3525_GPIO3_BASE AS3525_GPIO4_BASE 0xC80B0000 0xC80C0000 0xC80D0000 0xC80E0000 Offset: 0x40C Bit 7:0 Bit Name GPIO interrupt event register GPIO interrupt event register Bits set to HIGH configure the corresponding pin to detect rising edges or high levels, depending on the corresponding bit value in GPIO interrupt sense register (GPIO1_IS, …). Clearing a bit configures the pin to detect falling edges or low levels, depending on the corresponding bit value in GPIO interrupt sense register (GPIO1_IS, …). All bits are cleared by a reset. Default 00000000 Access RW Bit Description 0: falling edges, or low levels on corresponding pin trigger interrupts. 1: rising edges, or high levels on corresponding pin trigger interrupts. GPIO interrupt mask register Table 34 GPIO interrupt mask register Name Base Default GPIO1_IE GPIO2_IE GPIO3_IE GPIO4_IE AS3525_GPIO1_BASE AS3525_GPIO2_BASE AS3525_GPIO3_BASE AS3525_GPIO4_BASE 0xC80B0000 0xC80C0000 0xC80D0000 0xC80E0000 Offset: 0x410 Bit 7:0 Bit Name GPIO interrupt mask register GPIO interrupt mask register Bits set to HIGH allow the corresponding pins to trigger their individual interrupts and the combined GPIOINTR line. Clearing a bit disables interrupt triggering on that pin. All bits are cleared by a reset. Default 00000000 Access RW Bit Description 0: corresponding pin interrupt is masked. 1: corresponding pin interrupt is not masked. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 53 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential GPIO raw interrupt status register Table 35 GPIO raw interrupt status register Name Base Default GPIO1_RIS GPIO2_RIS GPIO3_RIS GPIO4_RIS AS3525_GPIO1_BASE AS3525_GPIO2_BASE AS3525_GPIO3_BASE AS3525_GPIO4_BASE 0xC80B0000 0xC80C0000 0xC80D0000 0xC80E0000 Offset: 0x414 Bit 7:0 Bit Name GPIO raw interrupt status register GPIO raw interrupt status register Bits read HIGH reflect the status of interrupts trigger conditions detected (raw, prior to masking), indicating that all the requirements have been met, before they are finally allowed to trigger by GPIO interrupt mask register (GPIO1_IE, ...). Bits read as LOW indicate that corresponding input pins have not initiated an interrupt. This register is read only, its bits are cleared by a reset. Default 00000000 Access R Bit Description Reflect the status of interrupts trigger conditions detection on pins (raw, prior to masking). 0: requirements not met on corresponding pins. 1: requirements met by corresponding pins. GPIO masked interrupt status register Table 36 GPIO masked interrupt status register Name Base Default GPIO1_MIS GPIO2_MIS GPIO3_MIS GPIO4_MIS AS3525_GPIO1_BASE AS3525_GPIO2_BASE AS3525_GPIO3_BASE AS3525_GPIO4_BASE 0xC80B0000 0xC80C0000 0xC80D0000 0xC80E0000 Offset: 0x418 Bit 7:0 Bit Name GPIO masked interrupt status register GPIO masked interrupt status register Bits read HIGH reflect the status of input lines triggering an interrupt. Bits read as LOW indicate that either no interrupt has been generated, or the interrupt is masked. This register shows the state of the interrupt after masking. This register is read-only. All bits are cleared by a reset. The contents of this register are made available externally through the intra-chip (or on-chip) GPIO1_MIS, ... signals. Default 00000000 Access R Bit Description Masked value of interrupt due to corresponding pin. 0: PrimeCell GPIO line interrupt not active. 1: PrimeCell GPIO line asserting interrupt. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 54 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential GPIO interrupt clear register Table 37 GPIO interrupt clear register Name Base Default GPIO1_IC GPIO2_IC GPIO3_IC GPIO4_IC AS3525_GPIO1_BASE AS3525_GPIO2_BASE AS3525_GPIO3_BASE AS3525_GPIO4_BASE 0xC80B0000 0xC80C0000 0xC80D0000 0xC80E0000 Offset: 0x41C Bit 7:0 Bit Name GPIO interrupt clear register GPIO interrupt clear register Setting a bit to HIGH in this register clears the corresponding interrupt edge detection logic register. Setting a bit to LOW in this register has no effect. This register is writeonly. All bits are cleared by a reset. Default 00000000 Access W Bit Description 0: has no effect. 1: clears edge detection logic. GPIO mode control select register Table 38 GPIO2, GPIO3 mode control select register Name Base Default GPIO2_AFSEL GPIO3_AFSEL AS3525_GPIO2_BASE AS3525_GPIO3_BASE 0xC80C0000 0xC80D0000 Offset: 0x420 Bit 7:0 Bit Name GPIO mode control select register GPIO mode control select register Setting a bit to HIGH in this register selects DBOP control for the corresponding PrimeCell GPIO line. All bits are cleared by a reset. Default 00000000 Access RW Bit Description 0: enables software control mode on corresponding pin. Bits 1: enables DBOP control mode on corresponding pin. Table 39 GPIO1, GPIO4 mode control select register Name Base Default GPIO1_AFSEL GPIO4_AFSEL AS3525_GPIO1_BASE AS3525_GPIO4_BASE 0xC80B0000 0xC80E0000 Offset: 0x420 Bit 7:0 Bit Name GPIO mode control select register GPIO mode control select register Not used. If bit set to HIGH, the corresponding pin will be set to 1. Default 00000000 Access RW Bit Description Bits 0: enables software control mode on corresponding pin. Bits 1: corresponding pins set to 1. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 55 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.5 MCI – SD / MMC Card Interface Features • • • Conformance to Multimedia Card Specification v2.11 Conformance to Secure Digital Memory Card Physical Layer Specification, v0.96 uses multimedia card bus or SD card bus. The PrimeCell™ MCI provides an interface between the APB system bus and multimedia and/or secure digital memory cards. It consists of two parts: • • The PrimeCell™ MCI adapter block includes the clock generation unit, the power management control, command and data transfer the APB interface provides access to the MCI adapter registers, and generates interrupt and DMA request signals. Figure 21 Multimedia Card Interface Block Diagram The connections to the Multimedia Card Interface are shared with the General Purpose I/O port-D (GPIO xpd[0:7]). Following diagram shows the external circuit elements for connection to a SD card adapter. Note that a feedback clock must be routed back to xpd[6]/mci_fbclk. Figure 22 Connecting SD / MC to GPIO-D © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 56 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.6 I2cAudMas - I2C audio master interface This is the control interface between the digital and the audio-part. The corresponding signal lines are connected inside of the MCM on the BGA substrate. For test purposes of the audio chip only, the signals are available at dedicated balls. • • • • • • • • • • • The key features of this interface block are: serial 2-wire I2C bus master supports standard (100 kbps) and fast speed (400kbps) 7-bit addressing sub-addressing programmable clock divider programmable transfer count soft reset bit interrupt generation (on RX Full, TX Empty, RX Overrun, no acknowledge received) status register test register Figure 23 I2C Audio Master Interface Block Diagram Table 40 I2C Audio Master Registers Register Name I2C2_DATA I2C2_SLAD0 I2C2_CNTRL I2C2_DACNT I2C2_CPSR0 I2C2_CPSR1 I2C2_IMR I2C2_RIS I2C2_MIS I2C2_SR I2C2_INT_CLR I2C2_SADDR I2C2_TESTIN I2C2_TESTOUT1 I2C2_TESTOUT2 Base Address AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE AS3525_I2C_AUDIO_BASE Offset 0x00 0x04 0x0C 0x10 0x1C 0x20 0x24 0x28 0x2C 0x30 0x40 0x44 0x50 0x54 0x58 Note transmit/receive FIFO data register slave ID register control register master data count register clock prescale register 0 clock prescale register 1 interrupt mask register raw interrupt status register masked interrupt status register I2C status register interrupt clear register sub-address register test register (monitors state of SCL and SDA) test mode register for driving output interrupt test mode register for driving SCLout, SCLOEn, SDAOUT and SDAOEN signals © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 57 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.7 I2CMSI - I2C master/slave interface This is a general control interface for chip-to-chip communication. The corresponding IOs are either used by the general purpose port C (xpc[6:7]) or by this I2C interface. The features of this interface block are: • • • • • • • • • • serial 2-wire I2C bus master supports standard (100 kbps) and fast speed (400kbps) supports multi-master system architecture programmable clock divider programmable transfer count programmable slave wait enable (for slave mode of operation, insertion of wait on the bus) soft reset bit interrupt generation (on RX Full, TX Empty, RX Overrun, no acknowledge received) status register test register Figure 24: I2C Interface Table 41 I2C Interface Registers Register Name I2C1_DATA I2C1_SLAD0 I2C1_SLAD1 I2C1_CNTRL I2C1_DACNT I2C1_SEAD0 I2C1_SEAD1 I2C1_CPSR0 I2C1_CPSR1 I2C1_IMR I2C1_RIS I2C1_MIS I2C1_SR I2C1_TXCNT I2C1_RXCNT I2C1_TX_FLUSH I2C1_INT_CLR I2C1_TESTIN I2C1_TESTOUT1 I2C1_TESTOUT2 Base Address AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE AS3525_I2C_MS_BASE Offset 0x00 0x04 0x08 0x0C 0x10 0x14 0x18 0x1C 0x20 0x24 0x28 0x2C 0x30 0x34 0x38 0x3C 0x40 0x50 0x54 0x58 Note transmit/receive FIFO data register slave ID register 0 slave ID register 1 control register master data count register self ID of slave 0 self ID of slave 1 clock prescale register 0 clock prescale register 1 interrupt mask register raw interrupt status register masked interrupt status register I2C status register transmit Fifo data count register receive Fifo data count register TX Fifo flush register interrupt clear register test register (monitors state of SCL and SDA) test mode register for driving output interrupt test mode register for driving SCLout, SCLOEn, SDAOUT and SDAOEN signals © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 58 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.8 I2SIN - I2S input interface The I2S input interface module (called I2SINIF module hereafter) is used to connect an external audio source to the processor system. The communication is based on the standardized I2S interface. The interface module connects to the processor system using the AMBA APB bus. All the input left & right channel data are mapped to either 14 or 24 bit format, selectable within the control register. If the data word length is less than 24 bit, the unused lower bits are set to zero. To reduce the interrupt frequency for the processor, a FIFO buffer is provided. The buffer can hold up to 32 words of 48 bit length (left plus right channel). Generation of interrupt request signal with several maskable interrupt sources (Pop Full, Pop Empty, Pop Error, Push Error, …etc) The I2SINIF provides the following features: • • • • • two independent clock domains: AMBA APB clock PCLK, I2S input clock i2si_sclk FIFO (32 words/48 bit) separating clock domains support of several oversampling rates: 128x, 256x, 512x interrupt support for FIFO data read DMA support for FIFO data transfer The I2SINIF provides five different modes: • • • • • input from on-chip audio ADC input from external audio ADC in master mode (SCLK, LRCK generated by external ADC) input from external audio ADC in slave mode (SCLK, LRCK, MCLK generated internally and fed to external ADC) input from SPDIF (SPDIF to I2S converter) feedback mode with input from I2S output interface: used for test purposes Figure 25 I2S Input Interface © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 59 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.8.1 I2S Input Register Mapping I2S Input Interface Registers Table 42 I2S Input Interface Registers Register Name Base Address Offset Note I2SIN_CONTROL AS3525_I2SIN_BASE 0x0000 Control register I2SIN_MASK AS3525_I2SIN_BASE 0x0004 Interrupt mask register I2SIN_RAW_STATUS AS3525_I2SIN_BASE 0x0008 Raw status register I2SIN_STATUS AS3525_I2SIN_BASE 0x000C Status register I2SIN_CLEAR AS3525_I2SIN_BASE 0x0010 Interrupt clear register I2SIN_DATA AS3525_I2SIN_BASE 0x0014 Audio data register I2SIN_SPDIF_STATUS AS3525_I2SIN_BASE 0x0018 SPDIF status signals register Table 43 I2S Input Control Register Name Base Default I2SIN_CONTROL AS3525_I2SIN_BASE 0x04 Offset: 0x0000 Control register 12 bit wide read/write register containing the control bits of the I2SINIF. Bit 11 Bit Name DMA_req_en 0 Default Access R/W 10 mclk_invert 0 R/W 9,8 i2s_clk_source 00 R/W 7,6 sdata_source 00 R/W 5 14bit_mode 0 R/W 4 sclk_idle 0 R/W 3 SDATA_valid 0 R/W 2 sclk_edge 1 R/W 1,0 osr 00 R/W Bit Description DMA request enable 0: disable 1: enable Invert MCLK 0: disable (SCLK changes at MCLK’s falling edge) 1: enable (SCLK changes at MCLK’s rising edge) Define the source of SCLK and LRCK for I2SINIF 00: SCLK and LRCK from I2SOUTIF (used if AFE sends data) 01: SCLK and LRCK from external ADC device (outside AS3525) 10: SCLK and LRCK from SPDIF converter 11: SCLK and LRCK from I2SINIF’s clock controller Define the source of SDATA for I2SINIF 00: SDATA from AFE 01: SDATA from external ADC device (outside AS3525) 10: SDATA from SPDIF converter 11: loopback SDATA from I2SOUTIF (test purpose) 0: ADC data from FIFO transferred in two 32-bit words to I2SIN_DATA (first left and then right data as indicated by the stereo24_status bit) 1: ADC data from FIFO transferred in one 32-bit word to I2SIN_DATA Enable/disable SCLK for I2SINIF 0: SCLK enabled 1: SCLK disabled 0: SDATA ignored at first SCLK edge (I2S standard) 1: valid SDATA at first SCLK edge 0: data valid at negative edge of SCLK 1: data valid at positive edge of SCLK Oversampling rate (needed for generating sclk and lrck) 00: 128x 01: 256x 10: 512x 11: 128x © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 60 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential The following table shows the valid combinations for sdata_source (bit 7 and 6) and i2s_clk_source (bit 9 and 8) of the I2SIN_CONTROL register. sdata_source i2s_clk_source Description 00 00 default mode (AFE with AS3525) 01 00 external data, external clock 01 11 external data, internal clock 10 10 data and clock from SPDIF converter 11 00 loopback, internal data and clock Table 44 I2S Input mask register Bit 7 6 5 4 3 2 1 0 Name Base Default I2SIN_MASK AS3525_I2SIN_BASE 0x00 Offset: 0x0004 Interrupt mask register The interrupt mask register determines which status flags generate an interrupt by setting the corresponding bit to 1. Bit Name reserved I2SIN_MASK_PUER I2SIN_MASK_POE I2SIN_MASK_POAE I2SIN_MASK_POHF I2SIN_MASK_POAF I2SIN_MASK_POF I2SIN_MASK_POER Default 0 0 0 0 0 0 0 0 Access R/W R/W R/W R/W R/W R/W R/W R/W Bit Description stereo24_status cannot assert interrupt request 1 enables the FIFO PUSH error interrupt 1 enables the FIFO POP is empty interrupt 1 enables the FIFO POP is almost empty interrupt 1 enables the FIFO POP is half full interrupt 1 enables the FIFO POP is almost full interrupt 1 enables the FIFO POP is full interrupt 1 enables the FIFO POP error interrupt Table 45 I2S Input raw status register Name Base Default I2SIN_RAW_STATUS AS3525_I2SIN_BASE 0x00 Offset: 0x0008 Raw status register The read-only raw status register contains the actual bit values as reflected by the FIFO controller status signals. I2SIN_PUER and I2SIN_POER are static bits, since FIFO controller gives the PUSH/POP error bit only for one clock. This means that these two bits remain asserted until they are cleared in the I2SIN_CLEAR register. All other bits change state depending on the underlying logic, i.e. state of FIFO controller. Bit 7 Bit Name stereo24_status Default 0 Access R 6 5 4 3 2 1 0 I2SIN_PUER I2SIN_POE I2SIN_POAE I2SIN_POHF I2SIN_POAF I2SIN_POF I2SIN_POER 0 0 0 0 0 0 0 R R R R R R R Bit Description Status of write interface for 24 bit stereo mode 0: left audio sample will be transferred next 1: right audio sample will be transferred next 1 if FIFO PUSH error 1 if FIFO POP is empty 1 if FIFO POP is almost empty 1 if FIFO POP is half full 1 if FIFO POP is almost full 1 if FIFO POP is full 1 if FIFO POP error © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 61 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 46 I2S input status register Name Base Default I2SIN_STATUS AS3525_I2SIN_BASE 0x00 Offset: 0x000C Status register The status register is a read-only register. A read to this register returns the value of the raw status bits AND’ed with the corresponding mask of enable bits set in the mask register. Bit 7 Bit Name stereo24_status Default 0 Access R 6 5 4 3 2 1 0 I2SIN_PUER I2SIN_POE I2SIN_POAE I2SIN_POHF I2SIN_POAF I2SIN_POF I2SIN_POER 0 0 0 0 0 0 0 R R R R R R R Bit Description Status of write interface for 24 bit stereo mode 0: left audio sample will be transferred next 1: right audio sample will be transferred next 1 if FIFO PUSH error 1 if FIFO POP is empty 1 if FIFO POP is almost empty 1 if FIFO POP is half full 1 if FIFO POP is almost full 1 if FIFO POP is full 1 if FIFO POP error Table 47 I2S Input interrupt clear register Name Base Default I2SIN_CLEAR AS3525_I2SIN_BASE 0x00 Offset: 0x0010 Bit 7 6 5:1 0 Bit Name reserved I2SIN_clear_puer reserved I2SIN_clear_poer Interrupt clear register The interrupt clear register is a write-only register. The corresponding static status bit can be cleared by writing a 1 to the corresponding bit in the clear register. All other interrupt flags are level interrupts depending on the status of the FIFO. The bits are de-asserted depending on the FIFO controller. Default Access W W W W Bit Description Clear PUSH error interrupt flag Clear POP error interrupt flag I2SIN_DATA The I2SINIF provides a single 32 bit wide data register. The register is used to read the audio samples from FIFO. If 14 bit mode is selected, both the left and right data are made available in the same register. Otherwise in the 24 bit mode the left and right data are provided through the same register alternatively. The stereo24_status bit in the I2SIN_STATUS register provides information which channel’s data will be provided next. The 14bit_mode bit in the I2SIN_CONTROL register defines how the values are read from the FIFO. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 62 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.8.2 I2S Input Signals The following specifications signals are given: • • Data are valid at rising/falling edge of SCLK (depending on I2SI_CONTROL’s setting). The left and right channels are indicated by the LRCK signal. The timing diagram of the standard I2S interface signals from the ADC is shown below (Figure 29). Figure 26 - I2S standard timing diagram Tperiod(fsaudio) / 2 LRCK Tperiod(fsaudio) / 2 Left Channel Right Channel SCLK SDATA 24 bit X 23 2 1 0 X 23 2 1 0 While the I2S standard states that the LRCK line changes one clock cycle before the MSB is transmitted. If the ADC sends the MSB directly after LRCK line changes, the SDATA_valid bit in the I2SI_CONTROL register must be set. Figure 27 - I2S standard timing diagram with SDATA valid directly after LRC changes Tperiod(fsaudio) / 2 LRCK Tperiod(fsaudio) / 2 Left Channel Right Channel SCLK SDATA 24 bit 23 22 2 1 0 23 22 2 1 0 Assumption: The LRCK toggles every 32 clocks of SCLK. 7.3.8.3 Power Modes The I2SINIF contains two clock domains. The PCLK domain can be turned off in the clock controller. The SCLK clock domain can be turned off locally using the SCLK_idle bit in the I2SIN_CONTROL register. Note that the SCLK’s clock gating signal has to be synchronized with the SCLK clock in order to guarantee correct operation. If PCLK is turned off, no interrupt must be triggered by the I2SINIF module. The I2SI_MCLK clock can be turned on/off in the clock generation unit. 7.3.8.4 Loopback Feature On the AS3525 are two I2S interfaces: • I2SOUTIF is responsible to send values to the DAC of the audio chip via I2SO_SDATA • I2SINIF is responsible to receive audio values from ADC of the audio chip via I2SI_SDATA In the AS3525 both SDATA signals are provided as loopback signals (I2SO_FSDATA, I2SI_FSDATA): • I2SO_SDATA to I2SINIF: This loopback is mainly for testing the transmit and receive paths of both I2S interfaces. The loopback signal is called I2SO_FSDATA. • I2SI_SDATA to I2SOUTIF: This loopback feature allows the application to echo the input audio samples directly to a loudspeaker. The signal provided by the I2SINIF is called I2SI_FSDATA. In normal mode the I2SINIF pushes audio values into the FIFO based on the I2SI_SDATA signal. If the loopback feature is enabled, the sdata_source bit in the control register must be set to 3. The FIFO content is filled with audio values send by the I2SOUTIF (signal I2SO_FSDATA). NOTE: This feature will only be available if SCLK is the same for I2S input and output interface. For implementation the I2SO_FSDATA signal is simply routed through a multiplexer to the I2SI_SDATA interface. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 63 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.8.5 DMA Interface The I2SINIF supports DMA transfers. The DMA controller supports incrementing and non-incrementing (single address) addressing for source and destination. For I2SINIF the single-address mode is used. The address of the I2SI_DATA register is used as DMA source address. 7.3.8.6 The 24 bit Stereo DMA Mode In 24 bit stereo mode, right and left audio samples must be read separately from the FIFO. In single-address DMA-mode both data must be read from the same address. The I2SINIF is responsible to split up the 48 bit FIFO entries into two 24 bit samples. The 24 bit value can then be transferred via the 32 bit wide AMBA bus. The I2SINIF provides the data in a specific order: first the left value is sent, and afterwards the right value is provided. Then a left value follows, and so on. In the destination memory the words are stored incrementally as shown below. Address Value addr 0 LDATA 0 addr 1 RDATA 0 addr 2 LDATA 1 addr 3 RDATA 1 … … addr n*2 LDATA n addr n*2+1 RDATA n © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 64 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.9 SPDIF interface As part of the I2SIN module also a SPDIF receiver interface is included. This SPDIF interface works as converter from SPDIF-AES/EBU to I2S. The SPDIF-AES/EBU standard is a serial audio interface that conveys 2 time-multiplexed audio channels, the left and right channels, as is the case in audio stereo transmission. The two channels are encoded in a 64-bit frame. Each individual channel is encoded in a sub-frame that consists of a 4-bit preamble, followed by 24 bits of audio data and 4 control bits, in a total of 32 bits per sub-frame. The SPDIF-AES/EBU standard provides for LSB first, up to 24-bit audio samples, Samples of 20 bits or less may be used, in which case the 4 least significant bits may be used for a 12-bit monitoring channel, transmitted at 1/3 of the sample rate. Please refer to the SPDIF-AES/EBU, AES3 or IEC958 standard documentation for more information. Features • • • • • Feed-forward operation: extracts audio data from the SPDIF-AES/EBU input signal by sampling it with a fast clock signal which not necessarily related to the sample rate frequency Purely digital receiver solution, without need of an input PLL for synchronisation. The audio samples are output serially in I2S format. PLL interface to filter out the jitter and generate a jitter-free I2S output. Recognizes all common audio and video related sample frequencies and outputs a nibble code for each. 7.3.9.1 SPDIF register description Table 48 SPDIF status register Name Base Default I2SIN_SPDIF_STATUS AS3525_I2SIN_BASE 0x00 Offset: 0x0018 Bit 4:1 0 Bit Name spdif_sample_freq spdif_sync SPDIF status signals register This read-only register contains status information of the SPDIF interface. The spdif_sample_freq and spdif_sync status bits are directly derived from the SPDIF converter. In order to provide valid status bits, these signals must be synchronized with pclk, i.e. clk_i2sin. Default Access R R Bit Description Incoming sample frequency Recognition of sub-frame preamble 0: first sub-frame preamble not recognized 1: successful recognition of the first sub-frame preamble The following table shows the input sample rate in KHz according to the sample_freq_code (bit 5 to 1) in the I2SIN_SPDIF register. sample_freq_code Input Sample Rate (KHz) 0001 22.050 0010 24.000 0011 32.000 0100 44.100 0101 48.000 0110 64.000 0111 88.200 1000 96.000 1001 176.400 1010 192.000 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 65 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.10 I2SOUT - I2S output interface The I2S output interface module (called I2SOUTIF module hereafter) is used to connect the processor system to an audio DAC. The communication is based on the standardized I2S interface. The audio samples are transferred from the processor to the I2SOUTIF module using the AMBA APB bus. A FIFO for 128 dual-channel audio samples is provided as a data buffer. Furthermore, the module provides a set of data, control and status registers. The I2SOUTIF provides the following features: • • • • • • • two independent clock domains: AMBA APB clock PCLK, I2S output clock i2so_mclk FIFO (128 words with 36 bit) separating clock domains support of 16 and 18 bit audio samples clock generator for I2S clocks (LCLK, I2SO_SCLK) support of several oversampling rates: 128x, 256x, 512x interrupt support for FIFO data write DMA support for FIFO data transfer For data output, following modes are implemented: • • • • two 18 bit audio samples, one for each channel (R,L). The values are written to I2SO_DATA. two 16 bit audio samples, one for each channel (R,L). Both values are written to the 32-bit wide I2SO_DATA register at the same time. This mode is highly efficient for 32-bit processor architectures. one 18 bit mono audio sample; the sample is used for both channels (R and L). The value is written to the I2SO_DATA. one 16 bit mono audio sample; the sample is used for both channels (R and L). The value is written to the I2SO_DATA. Figure 28 I2SO Block Diagram 7.3.10.1 I2S Output Interface Registers Table 49 I2S Output Interface Registers Register Name Base Address Offset Note I2SOUT_CONTROL AS3525_I2SOUT_BASE 0x0000 Control register I2SOUT_MASK AS3525_I2SOUT_BASE 0x0004 Interrupt mask register I2SOUT_RAW_STATUS AS3525_I2SOUT_BASE 0x0008 Raw status register I2SOUT_STATUS AS3525_I2SOUT_BASE 0x000C Status register I2SOUT_CLEAR AS3525_I2SOUT_BASE 0x0010 Interrupt clear register I2SOUT_DATA AS3525_I2SOUT_BASE 0x0014 Audio data register © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 66 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 50 I2SOUT control register Name Base Default I2SOUT_CONTROL AS3525_I2SOUT_BASE 0x0C Offset: 0x0000 Control register 7 bit wide read/write register containing the control bits of the I2SOUTIF. Bit 6 Bit Name DMA_req_en 0 Default Access R/W 5 sdata_lb 0 R/W 4 mclk_invert 0 R/W 3 stereo_mode 1 R/W 2 18bit_mode 1 R/W 1,0 osr 00 R/W Bit Description DMA request enable 0: disable 1: enable I2SDATA loopback from I2SINIF 0: I2SOUT_SDATA source is I2SOUTIF’s FIFO 1: I2SOUT_SDATA source is loopback value from I2SINIF (signal I2SIN_FDATA) Invert MCLK 0: disable (SCLK changes at MCLK’s falling edge) 1: enable (SCLK changes at MCLK’s rising edge) Audio samples provided by processor 0: mono 1: stereo Bit width of audio samples provided by processor 0: 16 bit 1: 18 bit Oversampling rate 00: 128x 01: 256x 10: 512x 11: 128x CAUTION: The control bit sdata_lb can only be set, if the I2SIN_FSDATA is synchronous to I2SOUT_SCLK. This is the case if AFE is used together with the AS3525 (in this case the I2SINIF uses also I2SOUT_CLK). Table 51 I2S Output mask register Bit 7 6 5 4 3 2 1 0 Name Base Default I2SOUT_MASK AS3525_I2SOUT_BASE 0x00 Offset: 0x0004 Interrupt mask register The interrupt mask register determines which status flags generate an interrupt by setting the corresponding bit to 1. Bit Name reserved I2SOUT_MASK_POER I2SOUT_MASK_PUE I2SOUT_MASK_PUAE I2SOUT_MASK_PUHF I2SOUT_MASK_PUAF I2SOUT_MASK_PUF I2SOUT_MASK_PUER Default 0 0 0 0 0 0 0 0 Access R/W R/W R/W R/W R/W R/W R/W R/W Bit Description stereo18_status cannot assert interrupt request 1 enables the FIFO POP error interrupt 1 enables the FIFO PUSH is empty interrupt 1 enables the FIFO PUSH is almost empty interrupt 1 enables the FIFO PUSH is half full interrupt 1 enables the FIFO PUSH is almost full interrupt 1 enables the FIFO PUSH is full interrupt 1 enables the FIFO PUSH error interrupt © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 67 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 52 I2S output raw status register Name Base Default I2SOUT_RAW_STATUS AS3525_I2SOUT_BASE 0x00 Offset: 0x0008 Raw status register The read-only raw status register contains the actual bit values as reflected by the FIFO controller status signals. I2SOUT_POER and I2SOUT_PUER are static bits, since FIFO controller gives the PUSH/POP error bit only for one clock. This means that these two bits remain asserted until they are cleared in the I2SOUT_CLEAR register. All other bits change state depending on the underlying logic, i.e. state of FIFO controller. Bit 7 Bit Name stereo18_status Default 0 Access R 6 5 4 3 2 1 0 I2SOUT_POER I2SOUT_PUE I2SOUT_PUAE I2SOUT_PUHF I2SOUT_PUAF I2SOUT_PUF I2SOUT_PUER 0 0 0 0 0 0 0 R R R R R R R Bit Description Status of write interface for 18 bit stereo mode 0: left audio sample is expected next 1: right audio sample is expected next 1 if FIFO POP error 1 if FIFO PUSH is empty 1 if FIFO PUSH is almost empty 1 if FIFO PUSH is half full 1 if FIFO PUSH is almost full 1 if FIFO PUSH is full 1 if FIFO PUSH error Table 53 I2S output status register Name Base Default I2SOUT_STATUS AS3525_I2SOUT_BASE 0x00 Offset: 0x000C Status register The status register is a read-only register. A read to this register returns the value of the raw status bits AND’ed with the corresponding mask of enable bits set in the mask register. Bit 7 Bit Name stereo18_status Default 0 Access R 6 5 4 3 2 1 0 I2SOUT_POER I2SOUT_PUE I2SOUT_PUAE I2SOUT_PUHF I2SOUT_PUAF I2SOUT_PUF I2SOUT_PUER 0 0 0 0 0 0 0 R R R R R R R Bit Description Status of write interface for 18 bit stereo mode 0: left audio sample is expected next 1: right audio sample is expected next 1 if FIFO POP error 1 if FIFO PUSH is empty 1 if FIFO PUSH is almost empty 1 if FIFO PUSH is half full 1 if FIFO PUSH is almost full 1 if FIFO PUSH is full 1 if FIFO PUSH error © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 68 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 54 I2S output interrupt clear register Name Base Default I2SOUT_CLEAR AS3525_I2SOUT_BASE 0x00 Interrupt clear register The interrupt clear register is a write-only register. The corresponding static status bit can be cleared by writing a 1 to the corresponding bit in the clear register. All other interrupt flags are level interrupts depending on the status of the FIFO. The bits are de-asserted depending on the FIFO controller. Offset: 0x0010 Bit 7 6 5:1 0 Bit Name reserved I2SOUT_clear_poer reserved I2SOUT_clear_puer Default Access W W W W Bit Description Clear POP error interrupt flag Clear PUSH error interrupt flag I2SOUT_DATA The I2SOUTIF provides two 32 bit wide data registers. The registers are used to store the audio samples before they are written to the FIFO. The registers can be used in different modes depending on the setting of the I2SOUT_CONTROL register. Basically, there are four ways to fill the FIFO. The processor can provide • • two 18 bit audio samples, one for each channel (R,L). The values are written to I2SOUT_DATA. two 16 bit audio samples, one for each channel (R,L). Both values are written to the 32-bit wide I2SOUT_DATA register at the same time. This mode is highly efficient for 32-bit processor architectures. • one 18 bit mono audio sample; the sample is used for both channels (R and L). The value is written to the I2SOUT_DATA. • one 16 bit mono audio sample; the sample is used for both channels (R and L). The value is written to the I2SOUT_DATA. In 18 bit stereo mode the data in I2SOUT_DATA is interpreted either as left or right audio value. The stereo18_status bit in the I2SOUT_STATUS register provides the information which channel’s audio sample is expected next. The I2S Output Signals The following specifications signals are given: • • Data are valid at the rising edge of I2SO_SCLK. The MSB is left justified to the I2S frame identification (I2SO_LRCK). According to standard I2S definition, a delay of one clock cycle between transition of I2SO_LRCK and the data MSB is used. The timing diagram of the I2S interface signals for 18bit and 16bit DAC is shown below. Tperiod(fsaudio) / 2 Tperiod(fsaudio) / 2 I2SO_MCLK I2SO_LRCK Left Channel Right Channel I2SO_SCLK I2SO_SDATA 16 bit I2SO_SDATA 18 bit 15 2 17 1 0 2 15 1 0 17 2 1 0 2 1 0 Figure 29 - I2S output timing diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 69 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential For the relationship of the clocks following constraints must be met: • LRCK must change with the falling edge of MCLK while MCLK is low (constrained should be set to 40 % of the MCLK period, see figure below). • SDATA must change at the falling edge of SCLK. It will be read with the rising edge of SCLK. Figure 30 Clock constraints I2SO_MCLK I2SO_LRCK Lrck must change with falling edge, within 40 % of MCLK period I2SO_SCLK Sampling of I2S data by Cello IF with rising edge of SCLK I2SO_SDATA L15 L14 R15 R14 7.3.10.2 Power Modes The I2SOUTIF contains two clock domains. Each clock domain can be turned off separately. The I2SO_MCLK must be turned off in the global clock controller register. This is necessary, as the audio chip requires I2SO_MCLK and I2SO_SCLK not only for I2S output, but also I2S input (see I2SINIF). PCLK Idle Mode If the PCLK is turned off (by the clock controller) the I2SOUT_STATUS register can hold invalid data. However, no interrupt should be triggered if the I2SOUTIF is in idle mode. I2SO_MCLK Idle Mode If I2SO_MCLK is disabled (by the clock controller) no audio samples are read from the FIFO. The output signals remain unchanged until the I2SO_MCLK is enabled again. 7.3.10.3 Loopback Feature On the AS3525 are two I2S interfaces: • • I2SOUTIF is responsible to send values to the DAC of the audio chip via I2SO_SDATA I2SINIF is responsible to receive audio values from ADC of the audio chip via I2SI_SDATA In the AS3525 both SDATA signals are provided as loopback signals (I2SO_FSDATA, I2SI_FSDATA): • I2SO_SDATA to I2SINIF: This loopback is mainly for testing the transmission and reception paths of both I2S interfaces. The loopback signal is called I2SO_FSDATA. • I2SI_SDATA to I2SOUTIF: This loopback feature allows the application to echo the input audio samples directly to a loudspeaker. The signal provided by the I2SINIF is called I2SI_FSDATA. In normal mode the I2SOUTIF generates the I2SO_SDATA signal based on the contents of the FIFO. If the loop back feature is enabled, the SDATA_LB bit in the I2SOUT_CONTROL register must be set. NOTE: This feature will only be available if SCLK is the same for I2S input and output interface. For implementation the I2SI_FSDATA signal is simply routed through a multiplexer to the I2SO_SDATA interface. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 70 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.10.4 DMA Interface The I2SOUTIF supports DMA transfers. The DMA controller supports incrementing and non-incrementing (single address) addressing for source and destination. For I2SOUTIF the single-address mode is used. The address of the I2SOUT_DATA register is used as DMA destination address. Stereo 18 bit DMA Mode In 18 bit stereo mode, right and left audio samples must be transferred separately to the FIFO. In single-address DMA-mode both data must be written to the same address. The I2SOUTIF is responsible to put the two 18 bit samples together to a 36 bit word. This word is written into the 36 bit wide FIFO. The I2SOUTIF requires a specific ordering of the samples written to the I2SOUT_DATA register: first the left value must be written, and afterwards the DMA controller must write the right value. Then a left value can follow, a.s.o. The status bit stereo18_status shows which audio sample is expected. In order to set up a correct DMA transfer the values must be placed in the source memory as follows: Address Value addr 0 LDATA 0 addr 1 RDATA 0 addr 2 LDATA 1 addr 3 RDATA 1 … … addr n*2 LDATA n addr n*2+1 RDATA n © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 71 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.11 NAND Flash Interface The NAND FLASH interface module enables control of NAND flash devices. The design follows the hardware reference implementation described in SMIL (SmartMediaTM Interface Library), Hardware Edition 1.00, TOSHIBA Corporation, but has extensions to support the latest generation of NAND flash devices. Programming and Reading can be done either by direct access to/from data register (normal mode) or by using a FIFO (burst mode). NAF supports 8-bit and 16-bit transfers. Features • • • • • • • • • • • • • • • interface compliant to AMBA APB bus generation of interrupt request signal with several maskable interrupt sources (ready, empty, almost_empty…) hardware error detection (2 detect, 1 correct per 256 bytes block) for up to 8 *256 bytes (up to 24 ECC bytes) 8-bit and 16-bit transfer Mode fore X8/X16 devices big endian / little endian support DMA Mode Normal Mode Data/Mode/Status Register write/read on/from data register automatically generates read/write strobes Burst Transfer 36 x 32 bit FIFO for DMA/burst support read- & write controller for automatic data resizing (32bit <=> 8/16bit) and read/write control configurable strobe (low and high time) for higher PCLK clocks / lower speed NAND Flash devices little endian/ big endian selectable load interrupts when FIFO is ‘almost_empty’ & ’almost_full’ to ensure continuous data flow Figure 31 Block Diagram of NAND Flash Interface © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 72 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Figure 32 Connecting a NAND Flash 7.3.11.1 NandFlash Interface Registers Table 55 NAF registers Register Name Base Address Offset Note NAFCONFIG AS3525_NAND_FLASH_BASE 0x00 Configuration register NAFCONTROL AS3525_NAND_FLASH_BASE 0x04 Control register NAFECC AS3525_NAND_FLASH_BASE 0x08 Error correction code reg NAFDATA AS3525_NAND_FLASH_BASE 0x0C Data register NAFMODE AS3525_NAND_FLASH_BASE 0x10 Mode register NAFSTATUS AS3525_NAND_FLASH_BASE 0x14 Status register NAFMASK AS3525_NAND_FLASH_BASE 0x18 Interrupt mask register NAFFIFODATA AS3525_NAND_FLASH_BASE 0x1C buffered read/write data register NAFWORDS AS3525_NAND_FLASH_BASE 0x20 Words register NAFCLEAR AS3525_NAND_FLASH_BASE 0x24 Interrupt clear register NAFTEST AS3525_NAND_FLASH_BASE 0x28 Test register © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 73 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 56 NAF configuration register Name Base Default NAFConfig AS3525_NAND_FLASH_BASE 0x00 Offset 0x0000 Bit Bit Name NAF Configuration Register The register is used for basic setup. 8 or 16-bit data width, little or big endian can be selected. DMA and FIFO on/off can be controlled as well as duty cycle and duration of read & write signals. Default Access 0x00 R/W Bit Description low time (# of PCLK cycles + 1) of the output ‘naf_we_n’ (e.g. a value of 1 will keep naf_we_n at ‘0’ for 3 PCLK cycles during write) 19:16 write_strobe_low [3:0] 15:12 write_strobe_high [3:0] 0x00 R/W high time (# of PCLK cycles + 2) of the output ‘naf_we_n’ (e.g. a value of 0 will keep naf_we_n at ‘1’ for 2 PCLK cycles during write) 11:8 read_strobe_low [3:0] 0x00 R/W low time (# of PCLK cycles + 1) of the output ‘naf_re_n’ (e.g. a value of 2 will keep naf_re_n at ‘0’ for 3 PCLK cycles during read) 7:4 read_strobe_high [3:0] 0x00 R/W high time (# of PCLK cycles + 2) of the output ‘naf_re_n’ (e.g. a value of 0 will keep naf_re_n at ‘1’ for 2 PCLK cycles during read) 3 dma_on 0x0 R/W 0: DMA is disabled and all DMA request signals are tied to 1: DMA is enabled 2 fifo_staticreset_n 0x0 R/W 0: FIFO is reset 1: FIFO is enabled 1 big_endian 0x0 R/W 0: little endian (FIFO data word will be processed in the order word(7:0), word(15:8), word(23:16) and word(31:24) when x16_device is 0; word(15:0) and word(31:16) when x16_device is 1 1: big endian (FIFO data word will be processed in the order word(31:24), word(23:16), word(15:8) and word(7:0) when x16_device is 0; word(31:16) and word(15:0) when x16_device is 1 Note: big_endian is only supported for r/w access through register NAFFifodata 0 x16_device 0x0 R/W 0: X8 Device (for NAND flash with 8-bit data bus) 1: X16 Device (for NAND flash with 16-bit data bus) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 74 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 57 NAF control register Name Base Default NAFControl AS3525_NAND_FLASH_BASE 0x2 Offset 0x0004 Bit Bit Name NAFControl Register The NAFControl register controls read access and FIFO dynamic reset. Default Access Bit Description 1 read_strobe 0x1 W 1: triggers a FIFO reset pulse (when NAFConfig bit ‘fifo_staticreset_n’ is 1) The bit is cleared automatically in the next PCLK cycle. 0 fifo_reset_strobe 0x1 W 1: triggers one single read cycle on output ‘naf_re_n’. The bit is cleared automatically in the next PCLK cycle. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 75 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 58 NAF error correction register Name Base Default NAFEcc AS3525_NAND_FLASH_BASE 0x2 Offset 0x0008 Bit 32:0 Bit Name Nafecc [32:0] NAF Error correction code register The NAFEcc register offers access to the error correction code registers. Default 0x0001 Access R Bit Description This register can be accessed up to 8 times and contains the following data: 1.access => Line Parity Block1 2.access => Column Parity Block1** 3.access => Line Parity Block2 4.access => Column Parity Block2** 5.access => Line Parity Block3 6.access => Column Parity Block3** 7.access => Line Parity Block4 8.access => Column Parity Block4** (9.access => same as 1.access) Note: * Before access to NAFEcc registers is possible, NAFMode register has to be set to 0xd4 (after page write operation) or to 0x54 (after page read operation). NAFEcc register contents will be cleared if NAFMode register bits 6 and 5 are both ‘1’. ** Only bits 11 to 0 are relevant for column parity, other bits are ‘0’; The content of NAFEcc depends on the device type. X8 (8-bit data bus) devices: Line Parity Block1 : will contain the line Column Parity Block1 : will contain the column Line Parity Block2 : will contain the line Column Parity Block2 : will contain the column Line Parity Block3 : will contain the line Column Parity Block3 : will contain the column Line Parity Block4 : will contain the line Column Parity Block4 : will contain the column parity of byte 1 to 512 (after 512 r/w cycles) parity of byte 1 to 512 (after 512 r/w cycles) parity of byte 513 to 1024 (after 1024 r/w cycles) parity of byte 513 to 1024 (after 1024 r/w cycles) parity of byte 1025 to 1536 (after 1536 r/w cycles) parity of byte 1025 to 1536 (after 1536 r/w cycles) parity of byte 1537 to 2048 (after 2048 r/w cycles) parity of byte 1537 to 2048 (after 2048 r/w cycles) X16 (16-bit data bus) devices: Line Parity Block1 : will contain the line Column Parity Block1 : will contain the column Line Parity Block2 : will contain the line Column Parity Block2 : will contain the column Line Parity Block3 : will contain the line Column Parity Block3 : will contain the column Line Parity Block4 : will contain the line Column Parity Block4 : will contain the column parity of halfword(7:0) 1 to 512 (after 512 r/w cycles) parity of halfword(7:0) 1 to 512 (after 512 r/w cycles) parity of halfword(15:8) 1 to 512 (after 512 r/w cycles) parity of halfword(15:8) 1 to 512 (after 512 r/w cycles) parity of halfword(7:0) 513 to 1024 (after 1024 r/w cycles) parity of halfword(7:0) 513 to 1024 (after 1024 r/w cycles) parity of halfword(15:8) 513 to 1024 (after 1024 r/w cycles) parity of halfword(15:8) 513 to 1024 (after 1024 r/w cycles) Note: Read ECC is not performed in unbuffered READ mode (this means when CPU accesses the Nand Flash through the NAF_DATA registers) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 76 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 59 NAF data register Name Base Default NAFData AS3525_NAND_FLASH_BASE 0x0000 Offset 0x000C Bit 15:0 Bit Name NAFData Data Register The NAFData register offers unbuffered access to the data bus of the NAND flash device. Default 0x01 Access R/W Bit Description For X8 devices (8-bit data bus) only bits 7:0 are relevant, other bits are ignored For X16 devices (16-bit data bus) all are relevant Table 60 NAF mode register Name Base Default NAFMode AS3525_NAND_FLASH_BASE 0x00 Offset 0x0010 Bit 7 Bit Name write protection Mode register The NAFMode register controls NAND flash read/write/erase procedures. Default Access Bit Description 0x0 R/W 0: write protection is on 1: write protection is off (when ‘power_on’ is 1) 6:5 ecc [1:0] 0x0 R/W 0: error code correction disabled 1: error code correction enabled (when ‘ce’ is 1) 2: stop error code correction, disable read/write strobes and disable ‘naf_do’ (when ‘ce’ is 1). Use this mode when reading the NAFEcc register 3: Reset NAFEcc register contents, ‘ecc’ changes to value 1 (enable mode) automatically after the next PCLK cycle 4 ce 0x0 R/W controls ‘chip enable’ 0: output ‘naf_ce_n’ is set to ‘1’ (device is disabled) 1: output ‘naf_ce_n’ is set to ‘0’ (device is enabled) 3 - 0x0 R always ‘0’ 2 power_on 0x0 R/W 0: power off (all output enable signals are turned off) 1: power on 1 ale 0x0 R/W controls ‘address latch enable’ 0: output ‘naf_ale’ is set to ‘0’ 1: output ‘naf_ale’ is set to ‘1’ (Address Latch Cycle) 0 cle 0x0 R/W controls ‘command latch enable’ 0: output ‘naf_cle’ is set to ‘0’ 1: output ‘naf_cle’ is set to ‘1’ (Command Latch Cycle) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 77 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 61 NAF status register Name Base Default NAFStatus AS3525_NAND_FLASH_BASE - Offset 0x0014 Bit Bit Name Status Register The NAFStatus register contains information on the internal status. Defau lt Access Bit Description 13 fifo_error 0x0 R FIFO error signal 0: if FIFO is reset 1: if FIFO contains 36 words and FIFO push(write) has occurred or when FIFO contains 0 words and a FIFO pop(read) has occurred. The FIFO error will lock the FIFO and has to be reset by a reset of the FIFO (by setting NAFControl register bit 1 to ‘1’) 12 fifo_full 0x0 R FIFO full signal 0: if FIFO contains less than 36 words 1: if FIFO contains 36 words 11 fifo_almost_full 0x0 R FIFO almost_full signal 0: if FIFO contains less than 32 words 1: if FIFO contains more than or equal 32 words 10 fifo_almost_empty 0x0 R FIFO almost_empty signal 0: if FIFO contains more than 4 words 1: if FIFO contains less than or equal 4 words 9 fifo_empty 0x0 R FIFO empty signal 0: if FIFO contains more than 0 words 1: = when FIFO contains 0 words 8 strobe_ready 0x0 R read/write strobe ready signal 0: if read/write strobe ‘0’ (strobe active) 1: if read/write strobe ‘1’ (strobe inactive) 7 flash_ready 0x0 R synchronised NAND flash ready signal 0: if synchronised input ‘naf_busy_in_n’ is ‘0’ (busy) 1: if synchronised input ‘naf_busy_in_n’ is ‘1’ (ready) 6 got_fifo_error 0x0 R FIFO error indication (edge triggered) 0: if bit 6 of NAFClear register is set to ‘1’ 1: if FIFO contains 36 words and FIFO push(write) occurs or when FIFO contains 0 words and a FIFO pop(read) occurs. 5 got_fifo_full 0x0 R FIFO full indication (edge triggered) 0: if bit 5 of NAFClear register is set to ‘1’ 1: if FIFO contains 36. 4 got_fifo_high 0x0 R 3 got_fifo_low 0x0 R FIFO high indication (edge triggered) 0: if bit 4 of NAFClear register is set to ‘1’ 1: if FIFO gets full (36 words) or changes from 31 to 32 words (and when the NAFWords register is greater than 32). Note: When this bit gets ‘1’ during ‘Page Read’ mode, a new FIFO burst read of up to 32 words is possible. FIFO low indication (edge triggered) 0: if bit 3 of NAFClear register is set to ‘1’ 1: if FIFO gets empty or changes from 5 to 4 words (and when the NAND Flash requires more than 32 bytes/halfwords). Note: When this bit gets ‘1’ during ‘Page Programming’ mode, a new FIFO burst write of up to 32 words is possible © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 78 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Name Base Default NAFStatus AS3525_NAND_FLASH_BASE - Offset 0x0014 Bit Bit Name Status Register The NAFStatus register contains information on the internal status. Defau lt Access 2 got_empty_and_rdy 0x0 R 1 got_strobe_ready 0x0 R 0 got_flash_ready 0x0 R Bit Description NAFWords empty and Controller ready indication (edge triggered) 0: when bit 2 of NAFClear register is set to ‘1’ 1: when read/write strobe changes from ‘0’ to ‘1’ (end of strobe) and NAFWords register has become empty. Note: This bit is used to detect the end of a multiple read/write burst transaction Read/write strobe ready indication (edge triggered) 0: when bit 1 of NAFClear register is set to ‘1’ 1: when read/write strobe changes from ‘0’ to ‘1’ (end of strobe) Note: read/write strobes can last from 3 to 33 PCLK cycles depending on NAFConfig settings. NAFWords empty and Controller ready indication (edge triggered) 0: when bit 2 of NAFClear register is set to ‘1’ 1: when read/write strobe changes from ‘0’ to ‘1’ (end of strobe) and NAFWords register has become empty. Note: This bit is used to detect the end of a multiple read/write burst transaction © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 79 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 62 NAF interrupt mask register Name Base Default NAFMask AS3525_NAND_FLASH_BASE 0x0018 Offset 0x0018 Bit Bit Name Interrupt Mask Register The NAFMask register is used to mask/enable the internal interrupt requests. Default Access Bit Description 6 mask6 0x1 R/W Mask ‘FIFO error indication’ interrupt request 0: enable 1: masked 5 mask5 0x1 R/W Mask ‘FIFO full indication’ interrupt request 0: enable 1: masked 4 mask4 0x1 R/W Mask ‘FIFO high indication’ interrupt request 0: enable 1: masked 3 mask3 0x1 R/W Mask ‘FIFO low indication’ interrupt request 0: enable 1: masked 2 mask2 0x1 R/W Mask ‘NAFWords empty and Controller ready indication’ interrupt request 0: enable 1: masked 1 mask1 0x1 R/W Mask ‘Read/write strobe ready indication’ interrupt request 0: enable 1: masked 0 mask0 0x1 R/W Mask ‘NAND flash ready indication’ interrupt request 0: enable 1: masked © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 80 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 63 NAF FiFo Data register Name Base Default NAFFifodata AS3525_NAND_FLASH_BASE 0x0000 Offset 0x001c Bit 32:0 FIFO Data Register The NAFFifodata register offers access to the internal FIFO. Bit Name Fifodata [32:0] Default - Access R/W Bit Description Writing this register will push a word on the FIFO and the write address will be incremented by 1. When the FIFO is full (36 words) then a write access on the register is ignored and the FIFO ERROR status bit is set. Reading on this register will pop a word from the FIFO and the read address will be incremented by 1. When the FIFO is empty then a read access on the register is ignored and the FIFO ERROR status bit is set. Table 64 NAF interrupt mask register Name Base Default NAFWords AS3525_NAND_FLASH_BASE 0x0000 Offset 0x0020 Bit 32:0 Bit Name Words [32:0] Interrupt Mask Register The NAFWords register informs the controller about the maximum words to be transferred and controls the FIFO transfer both in interrupt and DMA mode. Default Access 0x0000 R/W Bit Description 0: FIFO based data transfer is disabled not 0: FIFO transfer is in progress Note: For page transfers (program or read) the initial number of words depends on the NAND flash device. For a page size of 512 bytes, an initial word value of 512/4 = 128 has to be written. For a page size of 2k bytes, an initial word value of 512 has to be used. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 81 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 65 NAF interrupt clear register Name Base Default NAFClear AS3525_NAND_FLASH_BASE 0x0018 Offset 0x0024 Bit Bit Name Clear Register The NAFClear register clears interrupt status information and re-enables interrupt detection. Default Access 6 clear6 - W 5 clear5 - W 4 clear4 - W 3 clear3 - W 2 clear2 - W 1 clear1 - W 0 clear0 - W Table 66 NAF test register Name Base Default NAFTest AS3525_NAND_FLASH_BASE 0x0000 Offset 0x0028 Bit Bit Description Reset of ‘FIFO error indication’ status bit 0: no action 1: bit 6 of NAFStatus is reset and interrupt 6 detection is enabled Reset of ‘FIFO full indication’ status bit 0: no action 1: bit 5 of NAFStatus is reset and interrupt 5 detection is enabled Reset of ‘FIFO high indication’ status bit 0: no action 1: bit 4 of NAFStatus is reset and interrupt 4 detection is enabled Reset of ‘FIFO low indication’ status bit 0:no action 1:bit 3 of NAFStatus is reset and interrupt 3 detection is enabled Reset of ‘NAFWords empty and Controller ready indication’ status bit 0:no action 1:bit 2 of NAFStatus is reset and interrupt 2 detection is enabled Reset of ‘Read/write strobe ready indication’ status bit 0: no action 1: bit 1 of NAFStatus is reset and interrupt 1 detection is enabled Reset of ‘Read/write strobe ready indication’ status bit 0:no action 1: bit 0 of NAFStatus is reset and interrupt 0 detection is enabled Bit Name 1 datainvert 0 fifotest Test Register The NAFTest register is used for functional tests of the FIFO. Default - Access Bit Description W 0: default mode 1: disables FIFO access by the internal controller => FIFO is accessed by APB interface only W 0: default mode 1: data word both on FIFO input and output is inverted © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 82 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.12 DBOP - Data Block Output Port Purpose of this ARM APB peripheral module is a high-speed data output port that can support data transfer to various display controllers based on synchronous control interfaces. Programmability of polarity and timing of the generated control signals makes it possible to support various kinds of displays. Example of a supported display controller is the Hitachi HD77766R LCDE controller. From the programmers point of view the DBOP module can be serviced by DMA accesses. With the large size of the data FIFO and the programmable interrupt request conditions the overhead for SW is minimised. Simple read instructions to read for example a status register of the LCD controller are also supported. The usage of this cell results in a great performance boost compared to the standard ARM GPIO PrimeCell™ architecture. Features • • • • • • • • • • • APB bus interface support for direct memory access (DMA) data output FIFO with 128 words (32 bit wide) 8 or 16 bit parallel data output (configurable) 4 control outputs - flexible programming of the signal waveforms with respect to polarity and timing programmable even/odd control output generation 8 or 16 bit parallel data input register with programmable read strobe programmable conditions for interrupt generation based on FIFO flags usage of FIFO for simple division of APB clock domain and output clock domain programmable data output rate in range of 0.05 to 4 MHz APB Clock & DBOP Clocks are synchronous. Figure 33 DBOP Block Diagram DBOP FiFo 128x32 Dual ported RAM 128x32 PRESETn PSEL 32 PENABLE PWRITE PADDR[11:2] PWDATA[31:0] Amba APB Interface PRDATA[7:0] PCLK 32 dbop_d[7:0] / xpc[7:0] dbop_d[11:8] / xpb[7:4] push FiFo push status Dout register pop symetric FiFo Controller lb_select, hb_select FiFo pop status dbop_d[15:12] c0 / xpb[0] Control Signal Generator c1 / xpb[1] c2 / xpb[2] c3 / xpb[3] Register Block dinStrobe dataValid 8 Din register din[7:0] DBOPDMASREQ DBOPDMABREQ DBOPDMACLR DMA Interface Interrupt Generator DBOPIRQ dbop_clk © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 83 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.12.1 DBOP register definitions Table 67 DBOP Registers Register Name DBOP_TIMPOL_01 DBOP_TIMPOL_23 DBOP_CTRL_REG DBOP_STAT_REG DBOP_DOUT_REG DBOP_DIN_REG Base Address AS3525_DBOP_BASE AS3525_DBOP_BASE AS3525_DBOP_BASE AS3525_DBOP_BASE AS3525_DBOP_BASE AS3525_DBOP_BASE Offset 0x00 0x04 0x08 0x0C 0x10 0x14 Note Timing and polarity for control 0 and 1 Timing and polarity for control 1 and 2 Control Register Status Register Data output register Data input register Timing & Polarity Control register TPC01 This register contains all information necessary for definition of control signals C0 and C1. Table 68 DBOP control registers C0 and C1 Register bits 31 30 29 28:24 23:19 18 17 16 15 14 13 12:8 7:3 2 1 0 Name c1_p0 c1_p1 c1_p2 c1_t1 c1_t2 c1_ev c1_od c1_qs c0_p0 c0_p1 c0_p2 c0_t1 c0_t2 c0_ev c0_od c0_qs type r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w function polarity 1 polarity 2 polarity 3 Time 1 Time 2 even enable odd enable quiescent state polarity 1 polarity 2 polarity 3 Time 1 Time 2 even enable odd enable quiescent state default value 0 1 0 0xA 0x14 1 1 0 0 1 0 0xA 0x14 1 1 0 Timing & Polarity Control register TPC23 This register contains all information necessary for definition of control signals C2 and C3. Table 69 DBOP control registers C2 and C3 Register bits 31 30 29 28:24 23:19 18 17 16 15 14 13 12:8 7:3 2 1 Name c3_p0 c3_p1 c3_p2 c3_t1 c3_t2 c3_ev c3_od c3_qs c2_p0 c2_p1 c2_p2 c2_t1 c2_t2 c2_ev c2_od type r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w function polarity 1 polarity 2 polarity 3 Time 1 Time 2 even enable odd enable quiescent state polarity 1 polarity 2 polarity 3 Time 1 Time 2 even enable odd enable default value 0 1 0 0xA 0x14 1 1 0 0 1 0 0xA 0x14 1 1 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 84 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 0 c2_qs r/w quiescent state 0 Table 70 DBOP control register Register bits 31:22 21 Name type clr_pop_err W 20 clr_push_err W 19 en_data r/w 18 17 16 sdc res_even enw 15 14:13 function reserved Interrupt clear signal for pop error interrupt Interrupt clear signal for push error interrupt default value 0 0 0 r/w r/w r/w Tri-state enable for dout bus short count bit reset to even cycle enable write strd osm r/w r/w start read output serial mode 0 0 12 ow r/w output data width 0 11 ir_enable r/w IR enable 10 9 8 ir_po_err ir_pu_err ir_e_en r/w r/w r/w 7 ir_ae_en r/w 6 ir_af_en r/w 5 4:0 ir_f_en rs_t r/w r/w IR enable on pop error IR enable on push error IR enable set on push empty IR enable set on push almost empty IR enabbe set on push almost full IR enable set on push full read strobe time 0 0 0 Writing 1 to this bit will clear the pop error interrupt. Writing 0 has no effect. Writing 1 to this bit will clear the push error interrupt. Writing 0 has no effect . When set, dout bus is tri-stated when there is no active write on the bus. when set, next output cycle is even 0: write disabled 1: write enabled 0: 1: 2: 0: 1: 0: 1: single word out 2 serial words out 4 serial words out 8 bit data width 16 bit data width all IR disabled IR enabled 0 0 0 0 0 0 0x1F Notes: If the start read bit is issued by setting the strd bit to 1, a single read cycle is generated. After this read cycle the strd bit is set to 0 again by HW. If write is enabled by setting enw=1, no read is possible (strd does not cause any action). res_even is a reset bit that defines the start of even/odd generated signals. With res_even bit set, the next output cycle is a even cycle. Within this first even output cycle the res_even bit is set to 0 by the SW. sdc selects the counter length for the timing generator. Default is end value of 31. With sdc set to 1, the count end value is 15. en_data is used as a tri-state enable for the dout bus . When set as 1, dout is tri-stated if there is no active write on the bus . When this bit is set as 0, dout is bus is tri-stated only during the read cycle. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 85 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 71: DBOP status register Register bits 31:17 16 15:12 11 10 9 8 7 6 5 4 3 2 1 0 Name rd_d_valid Reserved fi_pu_err fi_pu_e fi_pu_ae fi_pu_hf fi_pu_af fi_pu_f fi_po_err fi_po_e fi_po_ae fi_po_hf fi_po_af fi_po_f type function r reserved read data valid f r r r r r r r r r r r push error push fifo empty push fifo almost empty push fifo half full push fifo almost full push fifo full pop error pop fifo empty pop fifo almost empty pop fifo half full pop fifo almost full pop fifo full default value The read data valid flag is cleared with every start read and set after read data strobe is issued (at read data valid 1 the data can be readout by SW). Data Output Register 32 bit register for data output - the data written to this register are directly written to the FiFo. Depending on the serial output mode and the output data width, the effective register width of this register is 8, 16 or 32 bits. Following table shows the effective data width for this register: odw = 0 odw = 1 osm=0 8 (byte0) 16 (HW0) osm=1 16 (byte0, byte1) 32 (HW0, HW1) osm=2 32 (byte0, byte1, byte2, byte3) 32 (HW0, HW1) Depending on odw, • either one, two or four bytes are transmitted serially for odw=0 • or one or two half words (HW = 16 bits) are transmitted serially for odw=1. Note that for the 8 or 16 bit width only a part of the FiFo memory is used (to keep HW design simple). Data Input Register 16 bit data input register that holds the value of the last read cycle. It is only valid if the data valid flag is set in the status register. No interrupt support is given, for data input the read data valid flag must be polled. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 86 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Dbop Integration Test Registers The Dbop module is programmed to integration test mode using test control register. The integration test mode enables the user to access all the input/output pins through the APB bus interface. Name DBOPITC DBOPITIP1 DBOPITOP1 Offset 0x18 0x1C 0x20 R/W R/W R/W R Reset Value 0x00000000 0x00 0x0 Description DBOP integration test control register DBOP integration test input register DBOP integration test output register Table 72 DBOPITC test register Register bits 31:1 0 Name type iten r/w function default value reserved Integration test enable 1 will enable the integration test mode Table 73 DBOPITIP1 test register Register bits 31:5 4 Name type function default value Testctrloen r/w 3 Testdataoen r/w 2 Testdmasreq r/w reserved Test value for out_enControl_n Test value for out_enData_n Test value for DMASREQ 1 Testdmabreq r/w Test value for DMABREQ 0 0 testirq r/w Test value for interrupt 0 0 The value on this bit will be reflected in out_enControl_n The value on this bit will be reflected in out_enData_n The value on this bit will be reflected in DBOPDMACSREQ The value on this bit will be reflected in DBOPDMACBREQ The value on this bit will be reflected in DBOPIRQ 0 0 Table 74 DBOPITOP1 test register Register bits 31:1 0 Name Testdmaclr type r function reserved DBOPDMACCLR test register. default value 0 Read of this register will return the value on the DBOPDMACCLR input. 7.3.12.2 DBOP DMA Interface This block generates all necessary interface signals with the DMAC primecell for DMA transfer. Following table gives a description of these signals. DBOPDMASREQ DBOPDMABREQ DBOPDMACLR single word request, asserted by DBOP. This signal is asserted when there is at least one empty location in the FiFo burst DMA transfer request, asserted by DBOP. This signal is asserted when there are at least four empty locations in the FiFo DMA request clear, asserted by DMA controller to clear the DMA request signals. If DMA burst transfer is requested, the clear signal is asserted during the transfer of the last data in the burst Symmetric FiFo The FiFo buffer has two main purposes: • data buffering: the FiFo contains 128 locations with 32 bits for data storage: with according DMA transfer, the data can be transferred in short time without need for any SW control © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 87 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential • clock domain crossing: the FiFo is at the boarder of clock domain PCLK and DBOPCLK. All necessary synchronisation is done internally. All flags are available as push flags (synchronised to the push clock PCLK) and pop flags (synchronised to the POP clk, which is synchronous to DBOPCLK. The FiFo controller gives empty, almost empty, half full, almost full and full flags which are available in two fashions: synchronous to the push or the pop side (pop_empty, push_empty, …). 7.3.12.3 Control Signal Generator Four independent control signals can be generated: typical application for such signals is a 80xx interface with RS, RD*, WR* and E or a 68xx interface with RS, E, RWN. The idea of this control signal generator is a general-purpose block, which generates any signal timing/waveform that is necessary to transfer the data to any specific display. Polarity Parameters For each of the control signals c0 - c3 following polarity parameters are defined: • • • p0 … polarity 0 at start of cycle p1 … polarity 1 following polarity 0 p2 … polarity 2 following polarity 1 Following figure shows an example for timing waveforms defined with these control parameters. Figure 34 DBOP timing waveform Tperiod T1 T2 D1 T1 T2 D2 P0, P1, P2 = 000 Static 0 P0, P1, P2 = 001 NRZ 1 P0, P1, P2 = 010 RZ 1 P0, P1, P2 = 011 NRZ 1 P0, P1, P2 = 100 RZ 1 P0, P1, P2 = 101 RO 1 P0, P1, P2 = 110 RZ 1 P0, P1, P2 = 111 Static 1 Quiescent State The control signals are only generated with each data output cycle (data output cycles are generated as long as the FiFo is not empty). With FiFo empty and in the absence of a read cycle, all control signals are set to a quiescent state. For each control signal, this quiescent state can be programmed either to 1 or 0. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 88 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Timing Parameters Also the time points for change from p0-p1 (t1) and p1-p2 (t2) can be programmed. For these programmable timing parameters each data output cycle is divided into 32 steps. Both T1 and T2 can be in the range of 0 to 31. For short count bit set (sdc bit in control register), T1 and T2 must be in the range of 0 to 15. Figure 35 DBOP timing parameters dout D0 Tperiod 0 10 20 30 P0, P1, P2 = 0,1,0; T1=6, T2=10 P0, P1, P2 = 1,0,1; T1=14, T2=28 P0, P1, P2 = 0,0,1; T1<21, T2=21 dinStrobe; TS = 24 Even/odd generated signals In addition to these timing parameters, signals can also be programmed to go active only during the even (0, 2, 4, …) or the odd cycles (1, 3, 5, …). For example the indication of even/odd bytes for the case that two bytes in serial are transmitted can be used. Two control bits are used to set this signal behaviour: evenEnable, oddEnable. For default, both are set to 1 and both cycles will appear. For cases where even or odd should be omitted, set according evenEnable/oddEnable to 0. With both set to 0, no cycles will appear at the output! Following example illustrates a typical waveform for an output interface where the evenEnable=0 and oddEnable=1 for control signal C2. In this example, C2 is an active high indication of the high byte (D1, D3, D5, …). Figure 36 DBOP even/odd generated signals waveforms quiescent state dout xx quiescent state even odd even D0 D1 D2 odd D3 even D4 odd D5 C0 = write C1 = enable C2 = high byte C3 = chip select Normally the even/odd cycles are toggling all the time, also if there are quiescent states in between. To have the possibility of defining a new start, reset of this even/odd counter can be done via the res_even bit inside of the control register. With res_even set, the counter starts with an even cycle. Res_even is then set to 0 again by SW at the new start. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 89 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Input strobe generation In addition to the generation of the control signals, also an input strobe signal dinStrobe is generated within the control signal generator. With active dinStrobe, the input data are strobed with rising clock edge (see DIN register). 7.3.12.4 Data Output Register The data output register handles different output widths and serial output mode (selected by parameters osm and odw). Following diagram illustrates the function of the data output register. Table 75 DBOP data output register high byte select Dout[15:7] data output register dout_reg[31:0] D3 D2 D1 D0 Dout[7:0] low byte select The control part generates the according signals for low byte select and high byte select. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 90 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.12.5 DIN register With the dinStrobe, data are written to the DIN register. This gives a simple mechanism, in which for example the status data can be read from a LCD display interface. To do a data read, first the START READ (strd) bit is programmed into the control register. With START READ, the control signal generator starts to generate one cycle with the according control signals. Data are strobed by the programmed strobe time into the din register. After the cycle is completed the HW resets the strd bit to 0. With set of the strd bit, the rd_data_valid bit is also reseted. The SW just has to poll the rd_data_valid bit, when the bit gets set the input data can be read from the din register. After read cycle, the control signal generator returns to the quiescent state. Following timing diagram shows an example of three read cycles. Figure 37 DBOP read cycle example Read cycle 0 Read cycle 1 Read cycle 2 C0 (= read_n) Data input xx D0 D1 D2 Read strobe DIN register D0 D1 D2 strd rd_data_valid Note: Be aware that the read cycle should only be activated when there is no active write cycle (FiFo is empty). Otherwise the results of such action get unpredictable. For any read cycle, the write enable bit must be set to 0 (write disabled). start read (strd) 0 0 0 0 1 1 1 1 write enable (wen) 0 0 1 1 0 0 1 1 FiFo empty Status 0 1 0 1 0 1 0 1 DBOP function quiescent quiescent valid write quiescent valid read valid read valid write quiescent 7.3.12.6 Interrupt Generator Depending on the FiFo Status, an interrupt request can be generated. The conditions that cause an interrupt are set within the control register. The interrupt output DBOPIRQ is active high. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 91 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.12.7 Clock frequencies The input clock is directly taken from the PCLK clock. A programmable prescaler is implemented within the CGU. Input clock for the prescaler is in the range of 20 - 60 MHz. Programmable division factors for the prescaler in the range of 1 to 8. Input clock to the module is in the range of 2.5 to 60 MHz. Within the module the control signal generator is doing a division by 16 or 32 (selectable). So the effective output data rates are in the range of 1.25 to 4 MHz for maximum performance and can be scaled down in the range of 0.07 to 0.25 MHz. Figure 38 DBOP data rate C0 PCLK (APB clock) Clock prescaler (inside CGU) clk_dbop predivider 1 to 8 c1 Control signal generator c2 c3 Divider /16 or /32 Output data rate 4.06 MHz 65 MHz ... 20 MHz 65 MHz 8.125 MHz 0.25 MHz 20 MHz 2.5 MHz 1.25 MHz 0.07 MHz Time constraining for the module should be done with 65 MHz, if there is a demand the time constraints for the output pads can be reduced. 7.3.12.8 Interface with GPIO PINs / additional PINs For the SW, the usage of either ARM primecell GPIO ports or DBOP port can be configured with the GPIOAFSEL registers. Following IO ports are used for the basic 8 bit interface xpc[7:0] xpb[3:0] for dout[7:0] and din[7:0] for {C3, C2, C1, C0} Following IO ports are used for the optional 16 bit interface xpb[7:4] dbop_d[15:12] for dout[11:8] and din[11:8] for dout[15:12] and din[15:12] © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 92 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.13 UART – Universal Asynchronous Receiver/Transmitter The UART is a Universal Asynchronous Receiver Transmitter compatible to industry standard 16550 with APB slave interface. This UART provides FIFO based transmitter-receiver pair with programmable Baud-rate, character widths and parity encoding. Status and error information is also provided by the design. Maximum baud rate supported by this UART is 1Mbps for input clock of 16MHz. Features • • • • • • • • • Compliance to Industry Standard 16550 UART. APB slave interface. Separate 16x8 Transmit and 16x11 Receive FIFOs. Programmable FIFO disabling for 1-byte depth. Programmable Baud rate Generator. Independent masking for transmit, receive and Error interrupts. False Start bit detection. Line Break generation and detection. Fully programmable serial interface characteristics: • Supports 5,6,7 and 8 bits. • even, odd, stick and no parity generation and detection. • 1, 11/2 and 2 stop bits. Figure 39 UART Block Diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 93 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.13.1 UART Baud Generator and Clock Divider Settings The internal baud generator module generates the required baud clock using the divisor register value. To achieve correct synchronizationincoming bits are over sampled by a factor of 16x. Software should program the divisor value by which the system clock has to be divided to achieve the required baud clock frequency. The equation to calculate baud divisor is Baud Divisor = (input frequency) ÷ (baud rate x 16) Important: the internal clock divider must be set to a value of 2 or higher. Setting the value to 1 (no division) is not allowed! For example, for 16 MHz PCLK clock following table gives the list of settings for different BAUD rates. Baud Rate 50 Required Baud clock frequency 800 Decimal divisor value 20000 75 1200 13333 110 1760 9091 134.5 2152 7435 150 2400 6667 300 4800 3333 600 9600 1667 1200 19200 833 1800 28800 556 2000 32000 500 4800 76800 208 7200 115200 139 9600 153600 104 19200 307200 52 38400 614400 26 56000 896000 18 128000 204800 8 250000 4000000 4 300000 4800000 3 500000 8000000 2 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 94 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.13.2 UART Register Descriptions All registers are 8 bits wide. Registers are selected based on the address and the value of Divisor Latch Select (DLS) bit in the line control register (UART_LNCTR_REG). Table 76 UART registers Register Name UART_DATA_REG UART_DLO_REG UART_DHI_REG UART_INTEN_REG UART_INTSTATUS_REG UART_FCTL_REG UART_LNCTL_REG UART_LNSTATUS_REG Base Address AS3525_UART_BASE AS3525_UART_BASE AS3525_UART_BASE AS3525_UART_BASE AS3525_UART_BASE AS3525_UART_BASE AS3525_UART_BASE AS3525_UART_BASE Offset 0x00 0x00 0x04 0x04 0x08 0x0C 0x10 0x14 DLS 0 1 1 0 Note Data register (Rx / Tx) Clock divider lower byte register Clock divider higher byte register Interrupt enable register Interrupt status register FIFO control register Line control register Line status register Table 77 UART Data Register Name Base Default UART_DATA_REG AS3525_UART_BASE 0xC8110000 Data register Holds the data byte received or the data byte to be transmitted respectively. RX: Offset: 0x00 DLS bit set to 0 This register holds the received data byte. In FIFO mode, this byte will be the top byte of the 16-byte FIFO. If FIFO mode is disabled, it will be the content of the receive shift register after a byte has been shifted in. A read to the address value 3b000 with Divisor Latch Select (DLS) bit 1’b0 will give the content of this register. If a character less than 8 bits is received, extra zero bits will be padded to this register. TX: This register contains the data to be transmitted. This register will be written by the processor. In FIFO mode, a write to this address will write data into the FIFO. In FIFO mode, top byte of txFIFO is passed on to transmitter shift register. If FIFO is disabled, a write to the address 3’b000 with DLS bit 1’b0 will write into this register. If FIFO is disabled, this register will be overwritten with new data. If FIFO is disabled, data in this register will be passed on to transmitter shift register. Bit 7:0 Bit Name UART_DATA_REG Default 00000000 Access RW Bit Description Holds the data byte received or the data byte to be transmitted respectively. Table 78 UART Clock divider lower byte register Bit 7:0 Name Base Default UART_DLO_REG AS3525_UART_BASE 0xC8110000 Offset: 0x00 DLS set to 1 Clock divider lower byte register This register holds the clock divider value (decimal) which is used to derive the baud clock. To achieve a desired baud rate, the baud clock should be 16-times higher then the baud rate. To derive this clock the ratio of the system clock and the required baud clock should be calculated and the value should be programmed into the clock divider lower byte and higher byte registers (UART_DLO_REG and UART_DHI_REG). Clock divider value = (input frequency) / (baud rate x 16) Bit Name UART_DLO_REG Default 00000000 Access W Bit Description This register holds the lower byte of the decimal divisor value to calculate baud clock. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 95 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 79 UART Clock divider higher byte register Bit 7:0 Name Base Default UART_DHI_REG AS3525_UART_BASE 0xC8110000 Offset: 0x04 DLS set to 1 Clock divider higher byte register This register holds the higher byte of the decimal divisor value to calculate baud clock. Bit Name UART_DHI_REG Default 00000000 Access W Bit Description This register holds the higher byte of the decimal divisor value to calculate baud clock. Table 80 UART Interrupt enable register Bit 7:3 2 1 0 Name Base Default UART_INTEN_REG AS3525_UART_BASE 0xC8110000 Offset: 0x04 DLS set to 0 Interrupt enable register This register will enable the three types of interrupts. Setting the bits of this register to logic 1 enables the selected interrupt. Bit Name Reserved lnStatusEn txDataEmptyEn rxDataRdyEn Default 00000 0 0 0 Access W W W Bit Description These bits are reserved for future use. This bit enables the “rxLineStatus” interrupt. This bit enables the “txDataEmpty” interrupt. This bit enables the “rxDataRdy” interrupt. Table 81 UART Interrupt status register Name Base Default UART_INTSTATUS_REG AS3525_UART_BASE 0xC8110000 Offset: 0x08 Interrupt status register This register will give the status of the interrupt. Depending on the enabled interrupt bits in the interrupt enable register (UART_INTEN_REG) different interrupts will be generated and the status will be updated in this register. On sensing an interrupt the software should read this register to get the status of the interrupt. Bit 7:3 2 Bit Name Reserved rxLineStatus Default 00000 0 RU 1 txDataEmpty 0 RU Access Bit Description These bits are reserved for future use. This interrupt is set on any error condition on the receive line. There are four types of error possibilities. These error conditions are set in bits 4:1 of the line status register (UART_LNSTATUS_REG). This bit is reset on a read of the line status register (UART_LNSTATUS_REG). In FIFO mode this bit is set when txFIFO is empty. If FIFO mode is disabled this interrupt is set if the data register (UART_DATA_REG (Tx)) is empty. This bit will be reset on write to the data register (UART_DATA_REG (Tx)). © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 96 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Name Base Default UART_INTSTATUS_REG AS3525_UART_BASE 0xC8110000 Offset: 0x08 Bit 0 Bit Name rxDataRdy Interrupt status register This register will give the status of the interrupt. Depending on the enabled interrupt bits in the interrupt enable register (UART_INTEN_REG) different interrupts will be generated and the status will be updated in this register. On sensing an interrupt the software should read this register to get the status of the interrupt. Default 0 Access RU Bit Description This is the data ready interrupt. In FIFO mode this bit is set when the number of bytes in the FIFO reaches the trigger level. This bit is also set in FIFO mode when a timeout occurs in the reception, i.e. Rx line idle for more than 4 char times and there is data in the FIFO. If FIFO mode is disabled this bit is set when one full byte is received. This bit is cleared when the FIFO is empty or the data register (UART_DATA_REG (Rx)) is read. Table 82 UART FIFO control register Name Base Default UART_FCTL_REG AS3525_UART_BASE 0xC8110000 Offset: 0x0C FIFO control register This register holds the control parameters to control receive (rx) and transmit (tx) FIFO. The parameters will enable the FIFOs, set the receiver trigger level, etc. Bit 7:5 4:3 Bit Name Reserved trigLevel Default 000 00 W 2 rxFIFORst 0 W 1 txFIFORst 0 W 0 FIFOModeEn 0 W Access Bit Description These bits are reserved for future use. These two bits will select the trigger level for the rxFIFO. Once the FIFO pointer reaches this level rxDataRdy interrupt is asserted. 00: 01 byte 01: 04 bytes 10: 08 bytes 11: 14 bytes This bit will reset rxFIFO pointers and clear all the bytes in the rxFIFO. This bit is self clearing, i.e. after resetting FIFO this bit will become zero. This bit will reset txFIFO pointers and clear all the bytes in the txFIFO. This bit is self clearing, i.e. after resetting FIFO this bit will become zero. This bit will enable the FIFO mode. By default this will be reset. Table 83 UART Line control register Name Base Default UART_LNCTL_REG AS3525_UART_BASE 0xC8110000 Offset: 0x10 Bit Bit Name Line control register This register controls the asynchronous data. Parameters in this register set the transmit and receive character format, the data length, parity bit, stop bit length, etc. Default Access Bit Description © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 97 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Name Base Default UART_LNCTL_REG AS3525_UART_BASE 0xC8110000 Offset: 0x10 Line control register This register controls the asynchronous data. Parameters in this register set the transmit and receive character format, the data length, parity bit, stop bit length, etc. Bit 7 Bit Name Default DLS 0 Access RW 6 breakCntl 0 RW 5 stickParity 0 RW 4 evenParity 0 RW 3 parityEn 0 RW 2 stopBits 0 RW 1:0 wordLenSel 00 RW Bit Description Divisor Latch Select Bit. This bit is used to select Divisor Latch registers. 1: Divisor Latch registers can be accessed. To access other registers this bit should be zero. 1: Will cause a break condition to be transmitted, i.e. TX line is pulled low. Normal transmission can be recovered once this bit is cleared. Transmitter logic can be used as break timer. 1: If this bit is set, along with parityEn a fixed parity bit will be transmitted and expected. This fixed parity bit will be the complement of the bit 4. 0: Data byte along with parity bit will be sent and expected to be odd parity. 1: Data byte along with the parity bit will be even parity. Enable parity bit. 0: Data byte will be transmitted and received without parity bit. 1: Will enable the parity bit at the end of the data byte. This bit decides how many stop bits should be sent along with a data byte. 0: 1 stop bit transmitted 1: 2 stop bits transmitted if 6, 7 or 8 bit wordLenSel 1: 1.5 stop bits transmitted if 5 bit wordLenSel Receiver will always check for one stop bit. These bits will select the number of data bits to be transmitted and received. 00: 5 bits 01: 6 bits 10: 7 bits 11: 8 bits Table 84 UART Line status register Name Base Default UART_LNSTATUS_REG AS3525_UART_BASE 0xC8110000 Offset: 0x14 Line status register This register holds the status information of the data transfer. It gives information about the received data. Bit 7 Bit Name FIFODataError 0 Default Access RU 6 5 Reserved txHoldRegEmpty 0 0 RU Bit Description 1: This bit is set when any data character in the FIFO has parity or framing error or break condition. 0: This bit is reset once the line status register (LINE_STATUS_REG) is read. This bit is reserved for future use. This bit is associated with the txDataEmpty interrupt. 1: Indicates that there is no data in txFIFO or the data register (UART_DATA_REG (Tx)). This bit is set once the data is shifted out. 0: This bit is reset once data is written into the data register (UART_DATA_REG (Tx)). © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 98 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Name Base Default UART_LNSTATUS_REG AS3525_UART_BASE 0xC8110000 Offset: 0x14 Line status register This register holds the status information of the data transfer. It gives information about the received data. Bit 4 Bit Name breakDetect Default 0 Access RU 3 framingError 0 RU 2 parityError 0 RU 1 overrunError 0 RU 0 dataReady 0 RU Bit Description This bit is associated with the rxLineStatus interrupt. 1: This bit is set if a break condition is detected, i.e. if a zero is detected on receive line for one full character duration. This condition will always cause framingError condition. This bit is associated with the rxLineStatus interrupt. 1: Indicates that the first stop bit of the received data byte is not valid, i.e. a zero is received in place of a one. This error condition causes the receiver to re-synchronize. This bit is associated with rxLineStatus interrupt. 1: Indicates that parity of the received data byte is different from the expected parity as set in the line control register (UART_LNCTL_REG). This bit is associated with the rxLineStatus interrupt. 1: Indicates an error condition which occurs when one character is fully assembled by the receiver but there is no space to write that byte. In FIFO mode, the content of the FIFO remains unaffected. If FIFO is disabled, the data register (UART_DATA_REG (Rx)) will be overwritten with the new data. 0: There is no data available. 1: There are one or more data bytes ready to be read by the processor. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 99 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.14 CGU - Clock generation unit The clock generation unit generates all clocks for all modules on the chip. • • • • • • • • • Hardware programmable selection of clock input either from internal oscillator or external clock input Two on-chip PLL circuits for generation of internal clocks Programmable divider for generation of ARM922T clock (fclk) Programmable divider for generation of AMBA bus clock (pclk) Support of ARM922T fastbus, synchronous and asynchronous mode Included clock gating registersto optimise power consumption Three clock busses at input of all dividers (clk_main, clk_a, clk_b) for utmost flexibility Spike-free switches between divider clock inputs (clk_main, clk_a, clk_b) Independent clock dividers for peripheral modules System startup At startup, the system is configured in a way to run without the need of PLLs. PLLs are disabled and clk_main is used for generation of the clock for the ARM controller (fclk) and ARM AMBA bus (pclk). Within the clock gating register, only the clocks that are really necessary for initial boot are enabled: clock for ARM, for the internal 1-TRAM memory, for the internal ROM and for the external memory. So the boot loader can start either from internal ROM or from the external MPMC. Clock switching The system can be reconfigured to run from PLLA or PLLB. Because the 1-TRAM is a dynamic memory that must always get the clock for the internal memory refresh, this switching must be implemented in a way that the PCLK clock is never stopped. The easiest solution to fulfil this requirement is always switching back to clk_main for reconfiguring the PLLs. After reprogramming of the PLLs it must be checked that the PLLs are locked before the system is switched onto the PLL output frequency. ARM922T and AMBA bus clock The ARM processor can run in different modes. These modes can be set within the iA, nF bits of the ARM922T CP15 (coprocessor) register 1. Fastbus mode This is the default mode after startup. The ARM922T input clock frequency is the same as the AHB/APB bus frequency. Synchronous mode Within the synchronous mode, the ARM922T frequency must be higher than the AHB/APB bus frequency and it must be an integer multiple of the AHB/APB bus frequency. Advantage of the synchronous mode is a higher performance because of less synchronisation effort between the ARM922T and the AHB bus. Asynchronous mode Within asynchronous mode, the ARM922T frequency must be higher than the AHB bus frequency, but it can be completely asynchronous. Disatvantage is a slightly reduced performance of the system because of the higher effort for synchronisation between the ARM922T and AHB clock domains. Block Diagram The block diagram on the following page gives a detailed view of the structure of the CGU. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 100 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Figure 40 Clock generation unit block diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 101 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.14.1 Input clock selection Input clock is either coming directly from the clk_ext pin or from the internal 24MHz crystal oscillator. Usage of external pin or internal oscillator is selected by the dedicated pin clk_sel. Table 85 Clock Selection Clk_sel Description 0 clk_main = clk_int 1 clk_main = clk_ext Three main internal clocks are generated as source for all clock dividers for all modules. • • clk_a, clk_b: the outputs of two independently configurable PLLs. clk_main: this clock is always available without the need of configuring any internal PLL An important constraint of the system is the memory type of the RAM: the internal 1-TRAM needs refresh cycles, with the following important restrictions: • the free running AHB/APB clock (PCLK) for the 1-TRAM must always be present: also for changing frequency settings, this must be taken into account (e.g. switch from clk_main to PLL output only after PLL is settled (start-up time). • the minimum frequency for the free running AHB/APB clock of the 1-TRAM is 20 MHz. Important note: Switching between the different frequencies must be done in a pre-defined order using the CGU-driver software. 7.3.14.2 Clock Gating For all peripheral clock domains clock gating is possible. Clock gating can be enabled/disabled by the corresponding bits within the clock control register CGU_PERI. After start-up, only the modules, which are necessary for booting the device, are enabled. These enabled peripherals are • • • • 1-TRAM controller and 1-TRAM macros external memory interface MPMC internal ROM vectored IR controller (VIC) 7.3.14.3 Interrupt generation An interrupt can be generated after the PLL is locked. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 102 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.14.4 PLL description • • • • • runs on single power supply at 1.2 V (special power PADs are used within the chip layout to guarantee lowest jitter: vddapll, vssapll which are connected to vdd_core, vss_core within the BGA substrate) fully integrated with internal loop filter VCO operating frequency from 200 - 400 MHz phase comparator input frequency from 2 - 8 MHz low power dissipation of typical 2.5 mW Figure 41 PLL block diagram Programming and calculation of the PLL output frequency The output frequency is controlled by three programmable dividers within the PLL. These dividers are: the input divider NR, the feedback divider NF and the output divider NO. The divider settings are programmed by bits within CGU_PLLA, CGU_PLLB registers. The table on the following page gives the detailed formulas for setting the PLL output frequency. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 103 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 86 Setting the PLL output frequency Input divider NR. NR = 16 * R4 + 8*R3 + 4*R2 + 2*R1 + R0 Feedback divider NF: NF = 2 * (128*F7 + 64*F6 + 32*F5 + 16*F4 + 8*F3 + 4*F2 + 2*F1 + F0) Output divider NO: Output divider setting OD0=0, OD1=0 OD0=1, OD1=0 OD0=0, OD1=1 OD0=1, OD1=1 NO (output divider value) Not allowed 1 2 4 The PLL output frequency is calculated with following formula Output frequency fout = NF ⋅ fin NR ⋅ NO Comparison frequency fref = fin NR VCO frequency fvco = NF ⋅ fin NR Following constraints must be followed for the comparison and output frequency: 2 MHz ≤ fref ≤ 8 MHz 200 MHz ≤ fVCO ≤ 400 MHz © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 104 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Clock Constraining Different clocks are constraint to different maximum clock speeds. As the clock frequencies can be set by software, care must be taken not to exceed these maximum clock frequencies. Table 879 Clock Constraining Clock Domain Max. Freq. [MHz] Description FCLK 250 Processor Clock PCLK 65 AHB/APB bus clock MPMC_CLK 90 MPMC (external memory interface) clock I2SI MCLK 65 I2S input interface master clock I2SO MCLK 30 I2S output interface master clock USB CLK 48 USB interface clock IDE CLK 90 IDE interface clock MS CLK 40 Memory Stick Interface clock Figure 42 Clock Generation Unit Block Diagram © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 105 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.14.5 Clock Generation Unit Registers Table 20 CGU Registers Register Name Base Address Offset Note CGU_PLLA AS3525_CGU_BASE 0x00 PLLA configuration register CGU_PLLB AS3525_CGU_BASE 0x04 PLLB configuration register CGU_PLLASUP AS3525_CGU_BASE 0x08 PLLA supervisor register CGU_PLLBSUP AS3525_CGU_BASE 0x0C PLLB supervisor register CGU_PROC AS3525_CGU_BASE 0x10 processor clock control register CGU_PERI AS3525_CGU_BASE 0x14 peripheral clock control register CGU_AUDIO AS3525_CGU_BASE 0x18 audio clock control register CGU_USB AS3525_CGU_BASE 0x1C USB clock control register CGU_INTCTRL AS3525_CGU_BASE 0x20 CGU interrupt mask and enable register CGU_IRQ AS3525_CGU_BASE 0x24 interrupt clear and lock status register CGU_COUNTA AS3525_CGU_BASE 0x28 PLLA lock counter register CGU_COUNTB AS3525_CGU_BASE 0x2C PLLB lock counter register CGU_IDE AS3525_CGU_BASE 0x30 IDE clock control register CGU_MS AS3525_CGU_BASE 0x34 Memory Stick clock control register CGU_DBOP AS3525_CGU_BASE 0x38 DBOP clock controller register Table 21 CGU_PLLA Register Name Base Default CGU_PLLA AS3525_CGU_BASE 0x00 Offset0x00 Bit Bit Name PLLA Configuration Register The CGU_PLLA register is used to configure the PLL A Default Access Bit Description 14:13 PLLA_OD [1:0] 0x00 R/W PLLA output divider control, 2 bit 12:8 PLLA_R [4:0] 0x00 R/W PLLA input divider control, 5-bit 7:0 PLLA_F [7:0] 0x00 R/W PLLA feedback divider control, 8 bit Table 22 CGU_PLLB Register Name Base Default CGU_PLLB AS3525_CGU_BASE 0x00 Offset0x04 Bit Bit Name PLLB Configuration Register The CGU_PLLB register is used to configure the PLL B Default Access Bit Description 14:13 PLLB_OD [1:0] 0x00 R/W PLLB output divider control, 2 bit 12:8 PLLB_R [4:0] 0x00 R/W PLLB input divider control, 5-bit 7:0 PLLB_F [7:0] 0x00 R/W PLLB feedback divider control, 8 bit © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 106 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 23 PLLA Supervisor Register Name Base Default CGU_PLLASUP AS3525_CGU_BASE 0x08 Offset0x08 Bit PLLA Supervisor Register This register contains control bits of the PLLA which are used very rarely, but have major impact on the functionality of the system. Bit Name Default Access Bit Description 3 PLLA_PD 0x00 R/W PLLA power down if SET 2 PLLA_OEB 0x00 R/W PLLA output enable, active low 1 PLLA_BP 0x00 R/W PLLA bypass if SET 0 PLLA_FIN_SEL 0x00 R/W PLLA clock source select 0: clk_int [PAD] 1: clk_ext [PAD] Table 24 PLBB Supervisor Register Name Base Default CGU_PLLBSUP AS3525_CGU_BASE 0x08 Offset0x0c Bit PLLB Supervisor Register This register contains control bits of the PLLB which are used very rarely, but have major impact on the functionality of the system. Bit Name Default Access Bit Description 3 PLLB_PD 0x00 R/W PLLB power down if SET 2 PLLB_OEB 0x00 R/W PLLB output enable, active low 1 PLLB_BP 0x00 R/W PLLB bypass if SET 0 PLLB_FIN_SEL 0x00 R/W PLLB clock source select 0: clk_int [PAD] 1: clk_ext [PAD] Table 25 Processor Clock Controller Register Name Base Default CGU_PROC AS3525_CGU_BASE 0x00 Offset0x10 Bit 7:4 Bit Name FCLK_POSTDIV_SEL [3:0] Processor Clock Controller Register This register contains control bits for ARM processor clock generation => FCLK. Default 0x00 Access R/W 3:2 FCLK_PREDIV_SEL [1:0] 0x00 R/W 1:0 FCLK_SEL[1:0] 0x00 R/W Bit Description post divider division ratio => post_div = 1/(fclk_postdiv_sel + 1) pre divider (fractional) division ratio 00: pre_div = 1/1 01: pre_div = 7/8 10: pre_div = 6/8 11: pre_div = 5/8 clkin select 00: clk_main 01: plla_fout 10: pllb_fout 11: reserved (clk_main) NOTE: f(fclk) := f(clkin) * pred_div * post_div; © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 107 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 26 Peripheral Clock Controller Register Name Base Default CGU_PERI AS3525_CGU_BASE 0x0F800000 Offset0x14 Bit Peripheral clock controller register This register allows setting the peripheral clocks. Bit Name Default Access Bit Description 28 MBIST_EN 0 R/W memory bist manager clock enable 27 EXTMEM_EN 1 R/W external memory clock enable 26 EXTMEMIF_EN 1 R/W external memory AHB IF clock enable 25 1TRAM_EN 1 R/W 1TRAM controller AHB IF clock enable 24 ROM_EN 1 R/W ROM AHB IF clock enable 23 VIC_EN 1 R/W vectored interrupt controller AHB IF clock enable 22 DMAC_EN 0 R/W DMA controller AHB IF clock enable 21 USB_EN 0 R/W USB controller AHB IF clock enable 20 I2SO_APB_EN 0 R/W I2Sout APB IF clock enable 19 I2SI_APB_EN 0 R/W I2Sin APB IF clock enable 18 I2C_EN 0 R/W I2C master/slave APB IF clock enable 17 I2C_AUDIO_EN 0 R/W I2C audio APB IF clock enable 16 GPIO_EN 0 R/W general purpose IO APB IF clock enable 15 SDMCI_EN 0 R/W secure digital/multimedia APB IF clock enable 14 NANDFLASH_EN 0 R/W NAND flash/Smart Media APB IF clock enable 13 UART_EN 0 R/W UART APB IF clock enable 12 WDOCNT_EN 0 R/W watchdog counter clock enable 11 WDOIF_EN 0 R/W watchdog timer module APB IF clock enable 10 SSP_EN 0 R/W synchronous serial port APB IF clock enable 9 TIMER1_EN 0 R/W timer module timer1 clock enable 8 TIMER2_EN 0 R/W timer module timer2 clock enable 7 TIMERIF_EN 0 R/W timer module APB IF clock enable division ratio div1 (AHB/APB clock) => div1 = 1/(pclk_div1_sel + 1) PCLK_DIV0_SEL division ratio div0 (ext. memory clock) => div0 = 5:2 0x0 R/W [3:0] 1/(pclk_div0_sel + 1) clkin select b’00: clk_main 1:0 PCLK_SEL[1:0] 0x0 R/W b’01: plla_fout b’10: pllb_fout b’11: fclk C AUTION : Clock gating takes effect immediately! Software must assure that all transactions to/from the module are finished before the clock is disabled. 6 PCLK_DIV1_SEL 0 R/W C AUTION : The peripheral clock must not exceed 65 MHz. The software must assure that requirement. Note: f(clk_extmem) := f(clkin) * div0; f(pclk) := f(clkin) * div0 * div1; © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 108 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 27 Audio Clock Controller Register Name Base Default CGU_AUDIO AS3525_CGU_BASE 0x00 Offset0x18 Bit Bit Name Audio Clock Controller Register This register allows setting the audio clock to I2S input and output interface. Default Access Bit Description 24 I2SI_MCLK2PAD_EN 0 R/W I2S audio input clock (I2SI_MCLK) to PAD connection enable 23 I2SI_MCLK_EN I2SI_MCLK_DIV_SEL [8:0] 0 R/W I2S audio input clock (I2SI_MCLK) enable 0x0 R/W I2Sin audio IF clock 1/(i2si_mclk_div_sel + 1) 0x0 R/W I2SI_MCLK clkin select 00: clk_main 01: plla_fout 10: pllb_fout 11: reserved (clk_main) 0 R/W I2S audio output clock (I2SO_MCLK) enable 0x0 R/W I2Sout audio IF clock 1/(i2so_mclk_div_sel + 1) R/W I2SO_MCLK clkin select 00: clk_main 01: plla_fout 10: pllb_fout 11: reserved (clk_main) 22:14 13:12 ISI_MCLK_SEL[1:0] 11 I2SO_MCLK_EN 10:2 I2SO_MCLK_DIV_SEL [8:0] 1:0 ISO_MCLK_SEL[1:0] 0x0 division division ratio ratio => => div_i = div_o = Note: The clock gating bits in this register apply only to the audio clocks. To enable/disable the APB parts of the corresponding I2S IF CGU_PERI has to be configured. f(i2si_mclk) := f(I2SI_mclk clkin) * div_i; f(i2so_mclk) := f(I2SO_mclk clkin) * div_o; © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 109 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 28 Processor USB Clock Controller Register Name Base Default CGU_USB AS3525_CGU_BASE 0x00 USB Clock ControllerRegister Offset0x1c This register allows setting the USB PHY interface clock. Bit Bit Name Default Access 5 USB_CLK_EN 0x00 R/W 4:2 USB_DIV_SEL [2:0] 0x00 R/W 1:0 USB_SEL[1:0] 0x00 R/W Bit Description USB PHY clock enable => clk_usb division ratio 0: div = 1/1 > 0: div = 1/(2*n); (even division factors only) clkin select 00: clk_main 01: plla_fout 10: pllb_fout 11: reserved (clk_main) Note: The clock gating bit applies only to the USB PHY clock. To enable/disable the clock to the AHB part (USB CORE) CGU_PERI has to be configured. f(clk_usb) = f(clk_core_48m) = f(clkin) * div; Table 29 Interrupt Mask and PLL Lock Status Register Name Base Default CGU_INTCTRL AS3525_CGU_BASE 0x00 Interrupt Mask and PLL Lock Status Register Offset: 0x20 Bit Bit Name Default Access Bit Description 3 INT_EN_PLLB_LOCK 0x00 R/W interrupt on PLLB lock enable (R/W) 2 INT_EN_PLLA_LOCK 0x00 R/W interrupt on PLLA lock enable (R/W) 1 PLLB_LOCK 0x00 R PLLB lock status, locked if SET (not cleared on read) 0 PLLA_LOCK R PLLA lock status, locked if SET (not cleared on read) Table 30 Interrupt Clear Register Name Base Default CGU_IRQ AS3525_CGU_BASE 0x00 Interrupt Clear Register Offset: 0x24 Bit Bit Name Default Access Bit Description 1 PLLB_LOCK 0x00 R PLLB lock status, locked if SET (not cleared on read) 0 PLLA_LOCK 0x00 R PLLA lock status, locked if SET (not cleared on read) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 110 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 31 PLL A Lock Counter Register Name Base Default CGU_COUNTA AS3525_CGU_BASE 0x20 PLL A Lock Counter Register Offset: 0x28 Bit 7:0 Bit Name COUNTA[7:0] Default 0x00 Access R/W Bit Description number of PLL A’s fout-clock cycles until the LOCKA bit is set Table 32 PLL B Lock Counter Register Name Base Default CGU_COUNTB AS3525_CGU_BASE 0x20 PLL B Lock Counter Register Offset: 0x2c Bit 7:0 Bit Name COUNTB[7:0] Default 0x00 Access R/W Bit Description number of PLL B’s fout-clock cycles until the LOCKB bit is set Table 33 IDE Clock Controller Register Name Base Default CGU_IDE AS3525_CGU_BASE 0x20 Offset: 0x30 Bit IDE Clock Controller Register This register allows setting the IDE interface clocks. Bit Name Default Access Bit Description 7 IDEIF_CLK_EN 0 R/W IDE AHB IF clock enable 6 IDE_CLK_EN 0 R/W IDE IF clock enable (90MHz domain) => clk_ide 5:2 IDE_DIV_SEL [2:0] 0x0 R/W division ratio => div = 1/(ide_div_sel + 1) R/W clkin select (clk_ide) 00: clk_main 01: plla_fout 10: pllb_fout 11: reserved (clk_main) 1:0 IDE_SEL[1:0] 0x0 Note: f(clk_ide) := f(clkin) * div; © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 111 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 34 Memory Stick (MS) Clock Controller Register Name Base Default CGU_MS AS3525_CGU_BASE 0x00 Offset: 0x34 Bit MS Clock Controller Register This register allows setting the MS interface clocks. Bit Name Default Access Bit Description 8 MSIF_CLK_EN 0 R/W MS APB IF clock enable 7 MS_CLK_EN 0 R/W MS IF clock enable (20/40MHz domain) => clk_ms 6:2 MS_DIV_SEL [2:0] 0x0 R/W division ratio => div = 1/(ms_div_sel + 1) R/W clkin select (clk_ms) 00: clk_main 01: plla_fout 10: pllb_fout 11: reserved (clk_main) 1:0 MS_SEL[1:0] 0x0 Note: f(clk_ms) = f(clkin) * div; Table 35 Data Block Output Port (DBOP) Clock Controller Register Name Base Default CGU_DBOP AS3525_CGU_BASE 0x00 Offset: 0x38 Bit DBOP Clock Controller Register This register allows setting the DBOP interface clocks. Bit Name Default Access Bit Description 3 DBOP_EN 0 R/W DBOP APB IF clock enable 2:0 DBOP_PREDIV_SEL [2:0] 0x0 R/W division ratio => div = 1/(dbop_prediv_sel + 1) Note: Setting DBOP_EN will enable both clocks (push/APB and pop) immediately. clk_dbop clock (pop clock) generation uses DBOP APB IF clock as input clock. f(clk_dbop) = f(PCLKDBOP) * div; © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 112 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Figure 43 Table with verified CGU frequency settings for Audio and USB applications with 24MHz crystal PLL PLL PLL fref fvco _F _R _OD [MHz] [MHz] Target: 48.000 Hz 48 24 41 23 6 3 8 5 1 3 2 3 plla_fout fclk_ fclk_ fclk [MHz] pre post [MHz] pclk_ pclk_ pclk div0 div1 [MHz] mclk mclk _div [Hz] faudio fsaudio error usb_ fusbphy [Hz] [%] div [Hz] fusb fsaudio CPU error target clock [%] [Hz] mode 4,000 8,000 3,000 4,800 384,000 384,000 246,000 220,800 384,000 96,000 123,000 55,200 0,00 0,00 0,00 0,00 5,00 1,00 1,00 0,00 64,000 48,000 61,500 55,200 0 0 0 0 0 0 0 0 64,000 48,000 61,500 55,200 61 15 19 8 6.193.548 6.000.000 6.150.000 6.133.333 48.387 0,806 46.875 -2,344 48.047 0,098 47.917 -0,174 3 48.000.000 0,000 1 48.000.000 0,000 48000 48000 48000 48000 fastbus fastbus fastbus fastbus 4,000 8,000 2,400 2,000 2,400 384,000 384,000 225,600 316,000 225,600 384,000 96,000 112,800 79,000 56,400 0 0 0 0 0 5 1 1 1 1 64,000 48,000 56,400 39,500 28,200 0 0 0 0 0 0 0 0 0 0 64,000 48,000 56,400 39,500 28,200 67 16 19 13 9 5.647.059 5.647.059 5.640.000 5.642.857 5.640.000 44.118 0,040 44.118 0,040 44.063 -0,085 44.085 -0,034 44.063 -0,085 3 48.000.000 0,000 1 48.000.000 0,000 44100 44100 44100 44100 44100 fastbus fastbus fastbus fastbus fastbus 4,000 8,000 4,000 3,429 384,000 384,000 328,000 212,571 384,000 96,000 82,000 53,143 0 0 0 0 5 1 1 1 64,000 48,000 41,000 26,571 0 0 0 0 0 0 0 0 64,000 48,000 41,000 26,571 93 22 19 12 4.085.106 4.173.913 4.100.000 4.087.912 31.915 -0,266 32.609 1,902 32.031 0,098 31.937 -0,197 3 48.000.000 0,000 1 48.000.000 0,000 32000 32000 32000 32000 fastbus fastbus fastbus fastbus 4,000 384,000 8,000 384,000 3,000 246,000 384,000 96,000 123,000 0 0 0 5 1 1 64,000 48,000 61,500 0 0 0 0 64,000 0 48,000 0 61,500 124 3.072.000 30 3.096.774 39 3.075.000 24.000 24.194 24.023 0,000 0,806 0,098 3 48.000.000 0,000 1 48.000.000 0,000 24000 fastbus 24000 fastbus 24000 fastbus 4,000 384,000 8,000 384,000 2,400 225,600 384,000 96,000 112,800 0 0 0 5 1 1 64,000 48,000 56,400 0 0 0 0 64,000 0 48,000 0 56,400 135 2.823.529 33 2.823.529 39 2.820.000 22.059 0,040 22.059 0,040 22.031 -0,085 3 48.000.000 0,000 1 48.000.000 0,000 22050 fastbus 22050 fastbus 22050 fastbus 4,000 384,000 8,000 384,000 4,000 328,000 384,000 96,000 82,000 0 0 0 5 1 1 64,000 48,000 41,000 0 0 0 0 64,000 0 48,000 0 41,000 187 2.042.553 46 2.042.553 39 2.050.000 15.957 -0,266 15.957 -0,266 16.016 0,098 3 48.000.000 0,000 1 48.000.000 0,000 16000 fastbus 16000 fastbus 16000 fastbus 4,000 384,000 8,000 384,000 4,000 328,000 384,000 96,000 82,000 0 0 0 5 1 1 64,000 48,000 41,000 0 0 0 0 64,000 0 48,000 0 41,000 249 1.536.000 62 1.523.810 52 1.547.170 12.000 0,000 11.905 -0,794 12.087 0,727 3 48.000.000 0,000 1 48.000.000 0,000 12000 fastbus 12000 fastbus 12000 fastbus 4,000 384,000 8,000 384,000 4,000 328,000 384,000 96,000 82,000 0 0 0 5 1 1 64,000 48,000 41,000 0 0 0 0 64,000 0 48,000 0 41,000 271 1.411.765 67 1.411.765 57 1.413.793 11.029 11.029 11.045 0,040 0,040 0,184 3 48.000.000 0,000 1 48.000.000 0,000 11025 fastbus 11025 fastbus 11025 fastbus 4,000 384,000 8,000 384,000 4,000 328,000 384,000 96,000 82,000 0 0 0 5 1 1 64,000 48,000 41,000 0 0 0 0 64,000 0 48,000 0 41,000 374 1.024.000 93 1.021.277 79 1.025.000 8.000 0,000 7.979 -0,266 8.008 0,098 3 48.000.000 0,000 1 48.000.000 0,000 8000 fastbus 8000 fastbus 8000 fastbus Target: 44.100 Hz 48 24 47 79 47 6 3 10 12 10 1 3 2 3 3 Target: 32.000 Hz 48 24 41 31 6 3 6 7 1 3 3 3 Target: 24.000 Hz 48 24 41 6 3 8 1 3 2 Target: 22.050 Hz 48 24 47 6 3 10 1 3 2 Target: 16.000 Hz 48 24 41 6 3 6 1 3 3 Target: 12.000 Hz 48 24 41 6 3 6 1 3 3 Target: 11.025 Hz 48 24 41 6 3 6 1 3 3 Target: 8.000 Hz 48 24 41 6 3 6 1 3 3 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 113 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.15 CCU - Chip Control Unit Following chapters describe the functions of the CCU. Table 88 CCU Registers Register Name Base Address Offset Note CCU_SRC AS3525_CCU_BASE 0x0000 Software reset control register CCU_SRL AS3525_CCU_BASE 0x0004 Software reset lock register CCU_MEMMAP AS3525_CCU_BASE 0x0008 Memory map register CCU_IO AS3525_CCU_BASE 0x000C IO configuration register CCU_SCON AS3525_CCU_BASE 0x0010 System configuration register CCU_VERS AS3525_CCU_BASE 0x0014 Chip version register CCU_SPARE1 AS3525_CCU_BASE 0x0018 spare register 1 (for future use) CCU_SPARE2 AS3525_CCU_BASE 0x001C spare register 2 (for future use) 7.3.15.1 Reset Controller • Generation of the internal reset: the external reset pin XRES is used to generate the internal global reset. This internal reset is synchronised to clk_main and the active reset time is enlarged. This is necessary to wait for the startup of the DC/DC converter and LDO's that are generating the supplies of the digital chip. The time assumed for this startup is 10 ms, therefore 2^18 cycles of clk_main are counted before the internal reset is released. This mechanism is also used for the WATCHDOG reset. • Softreset: for each module, the reset can also be generated by SW control. For this purpose, the SW can write to the software reset control register (CCU_SRC). To avoid unintended SW resets, the access to this control register is locked by the SW reset lock register (CCU_SRL). So the correct usage is: • write CCU_SRC • write CCU_SRL (magic number 0x1A720212) to CCU_LOCK to activate resets • write CCU_SRL (0x00000000) to deactivate resets Table 89 Software Reset Control Register Name Base Default CCU_SRC AS3525_CCU_BASE 0x00 Offset: 0x0000h Software Reset Control Register Writing a logic 1 to the single bits in the read/write register enables resets to each module. Bit 24 Bit Name DBOP_EN 0 Default Access R/W 23 MBIST_EN 0 R/W 22 SPDIF_EN 0 R/W 21 TIMER_EN 0 R/W 20 SSP_EN 0 R/W 19 WDO_EN 0 R/W 18 IDE_EN 0 R/W 17 IDE_AHB_EN 0 R/W 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: Bit Description enable DBOP reset disable DBOP reset enable MBIST manager reset disable MBIST manager reset enable SPDIF reset disable SPDIF reset enable timer module reset disable timer module reset enable synchronous serial port reset disable synchronous serial port reset enable watchdog timer module reset disable watchdog timer module reset enable compact flash/IDE reset (except AHB part) disable compact flash/IDE reset (except AHB part) enable compact flash/IDE’s AHB interface reset disable compact flash/IDE’s AHB interface reset © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 114 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Name Base Default CCU_SRC AS3525_CCU_BASE 0x00 Offset: 0x0000h Software Reset Control Register Writing a logic 1 to the single bits in the read/write register enables resets to each module. Bit 16 Bit Name UART_EN Default 0 Access R/W 15 NAF_EN 0 R/W 14 SDMCI_EN 0 R/W 13 GPIO_EN 0 R/W 12 I2C_AUDIO_EN 0 R/W 11 I2C_EN 0 R/W 10 MMS_EN 0 R/W 9 I2SI_APB_EN 0 R/W 8 I2SO_APB_EN 0 R/W 7 USB_AHB_EN 0 R/W 6 USB_PHY_EN 0 R/W 5 DMAC_EN 0 R/W 4 VIC_EN 0 R/W 3 RAMC_EN 0 R/W 2 1TRAM_EN 0 R/W 1 MPMC_EN 0 R/W 0 BRIDGE_EN 0 R/W 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: 1: 0: Bit Description enable UART interface reset disable UART interface reset enable NAND flash/Smart Media interface reset disable NAND flash/Smart Media interface reset enable secure digital/multimedia interface reset disable secure digital/multimedia interface reset enable general purpose IO reset disable general purpose IO reset enable audio I2C interface reset disable audio I2C interface reset enable master/slave I2C interface reset disable master/slave I2C interface reset enable memory stick interface reset disable memory stick interface reset enable I2S input interface reset for APB part disable I2S input interface reset for APB part enable I2S output interface reset for APB part disable I2S output interface reset for APB part enable USB AHB reset disable USB AHB reset enable USB PHY reset disable USB PHY reset enable DMA controller reset disable DMA controller reset enable vectored interrupt cell reset disable vectored interrupt cell reset enable RAMC reset disable RAMC reset enable 1TRAM reset disable 1TRAM reset enable external memory AHB reset disable external memory AHB reset enable bridge reset disable bridge reset Table 90 Software Reset Lock Register Name Base Default CCU_SRL AS3525_CCU_BASE 0x00 Offset: 0x0004h Bit 0:31 Bit Name software_reset_lock Software Reset Lock Register Use of this register enables the software reset selected with Software Reset Control Register. Writing a value of 0x1A720212 will enable the selected reset; writing any other value will not enable software reset. Default 0 Access R/W Bit Description 0x1A720212: enables selected reset Other values: no effect © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 115 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.15.2 IO_PADRING functions Within the IO_PADRING module all multiplexing for selecting alternative functions is implemented. The selection of active functions is chosen within the IO_configuration_register. Following table gives a description of the IO configurations: Table 91 IO_PADRING Configurations Name Base Default CCU_IO AS3525_CCU_BASE 0x00 IO Configuration Registers With this read/write registers the functionality of IOs are controlled which provides several different functions Offset: 0x000Ch Bit 8:7 Bit Name naf_ce_sel[1:0] 0 Default Access R/W 6 pll_probe_en 0 R/W 5 4 ide_sel spi_flash_mode 0 0 R/W R/W 3:2 xpd_func_sel(1:0) 0 R/W 1 0 i2c_ms_sel uart_sel 0 0 R/W R/W Bit Description these bits select which output is used for NAF ce_n. 0: naf_ce0_n 1: naf_ce1_n 2: naf_ce2_n 3: naf_ce3_n test mode: 1: pll output clock is available at a GPIO Pin 1: the IDE input/output configuration is set SPI used in master mode: 1: pin SSP_FSSOUT always 0 0: pin SSP_FSSOUT generated by SSP hardware block SPI used in slave mode: spi_flash_mode hast to be switched to 0 00: XPD works as general purpose IO 01: SD-MCI interface 10: the XPD[5:0] are configured to support MS, XPD[7:6} are general IO pins 11: reserved (XPD works as general IO) 1: the I2C master/slave IO configuration is set 1: the uart IO configuration is set 7.3.15.3 Other CCU functions With the CCU_MEMMAP register, the remap(r/w) and int_boot_sel (read only) bits are accessible. Table 92 Memory Map Register Name Base Default CCU_MEMMAP AS3525_CCU_BASE N/A Memory Map Register With the register the remap(r/w) and int_boot_sel (r only) bits are accessible. Offset: 0x0008h 1 Bit Bit Name INT_BOOT_SEL 0 REMAP Default external pin XPC[0] 0 Access R R/W Bit Description Boot selection 1: internal ROM 0: external memory interface Defines memory mapping 1: RAM 0: ROM If the INIT_BOOT_SEL is 0 (boot from external memory interface), following pins will be latched at startup to define the MPMC interface settings: • mpmc_stcs1mw[0] • mpmc_stcs1pb • mpmc_stcs1pol • mpmc_rel1config © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 116 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.3.15.4 Additional Chip Control Unit Registers Table 93 System Configuration Register Name Base Default CCU_SCON AS3525_CCU_BASE 0x00 Offset: 0x0010h Bit 0 Bit Name priority_config System Configuration Register This read/write register controls system parameters. Default 0 Access R/W Bit Description AHB master’s priority configuration: 0: Configuration A (default) Highest priority: TIC (Test Interface Controller) – for production test only 2 nd highest priority: ARM922T 3 rd highest priority: DMA 4 th highest priority: USB lowest priority: IDE 1: Configuration B Highest priority: TIC (Test Interface Controller) – for production test only 2 nd highest priority: DMA 3 rd highest priority: USB 4 th highest priority: IDE lowest priority: ARM922T Table 94 Chip Version Register Name Base Default CCU_VERS AS3525_CCU_BASE 0x09 Offset: 0x0014h Bit 31:12 11:0 Bit Name main_version_id(19 :0) sub_version_id(11: 0) Chip Version Register Version information can be read from this register. Default 0x2 Access R Bit Description main version ID 0x1 R sub version ID Table 95 Spare Register 1 Name Base Default CCU_SPARE1 AS3525_CCU_BASE 0x00 Offset: 0x0018h Bit 31:9 8 7 6 5 4 3:2 1:0 Bit Name spare dma_sreq_SSPRX_off dma_sreq_SSPTX_off dma_sreq_DBOP_off dma_sreq_I2Sin_off dma_sreq_I2Sout_off spare mpmc_clk_inv Metal ECO Spare Register This register implements 32bit spare FF’s. Use for metal ECO redesign. Defau lt 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 Access R/W R/W R/W R/W R/W R/W R/W R/W Bit Description spare bits to be used for metal ECO redesign if SET disableDMA single request of SSPRX module if SET disable DMA single request of SSPTX module if SET disable DMA single request of DBOP module if SET disable DMA single request of I2Sin module if SET disable DMA single request of I2Sout module if SET spare bits to be used for metal ECO redesign if SET spare bits used to invert output clocks mpmc_clk(1:0) if SET © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 117 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 96 Spare Register 2 Name Base Default CCU_SPARE2 AS3525_CCU_BASE 0x00 Offset: 0x001Ch Bit 31:3 2:0 Bit Name spare bist_idle_cycle_ctrl Metal ECO Spare Register This register implements 32bit spare FF’s. Use for metal ECO redesign. Defau lt 0x00 0x00 Access R/W R/W Bit Description spare bits to be used for metal ECO redesign if SET internal RAM refresh cycle control bits of BIST_MGR module 000: idle every 32nd cycle (default) 100: idle every 16th cycle 110: idle every 8th cycle 111: idle every 4th cycle © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 118 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4 Audio and Power Management functions 7.4.1 SYSTEM 7.4.1.1 General The system block handles the power up, power down and regulator voltage settings of the AFE. 7.4.1.2 Power Up The chip powers up when on of the following condition is true: • High signal on the PWR_UP pin (>80ms, >1V & >1/3 BVDD) • Input voltage on the UVDD pin (USB plug in: >80ms, BVDD>1.5V, UVDD>4.5V) • Input voltage on the CHG_IN pin (charger plug in: >80ms, BVDD>1.5V, CHG_IN>4.0V) • Input voltage on BVDD pin (battery change: >1.35V) To hold the chip in power up mode the PwrUpHld bit in the SYSTEM register (0x20h) is set. 7.4.1.3 Power Down The chip automatically shuts off if one of the following conditions arises: 1. Clearing the PwrUpHld bit in SYSTEM register (0x20h) 2. I2C watchdog power down if enabled (no serial reading for >1s, has to be enabled) 3. BVDD drops below the minimum threshold voltage (<2.7V) 4. Junction temperature reaches maximum threshold, set in SUPERVISOR register (0x24h) 5. High signal on the PWR_UP pin for more than (>6s, >1V & >1/3 BVDD). Figure 44 Power Up Timing Power up from PwrUp, CHG_IN, VBUS or RTCSUP pin BVDD rising with VBAT1 supply (DCDC3V) VREF, IREF rising with vdd_bandgap QLDO1 & 2 AVDD & DVDD for internal supply EN LDO2 + DCDC QLDO2=ok Enable CP Sequence start sequencer with 1.2 MHz clock VREF=ok Enable PVDD +2ms Enable IOVDD +4ms start up with length regulator (200mA) Enable CVDD +6ms +10ms charge pump (50mA) enable unlock, enable via I2C setting PowerGood = XRES +8ms © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 119 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.1.4 Parameter Table 97 Supply Regulator Block Characteristics Symbol Parameter Notes Min DVDD_POR_OFF DVDD_POR_ON POR_ON/OFF_HYST LRCK WATCHDOG F(LRCK)_WD_OFF ON_Delay Typ Max 2.15 2.0 100 4.1 50 Unit V V mV 8 kHz us DVDD=2.9V; Tamb=25ºC; unless otherwise specified 7.4.1.5 Register Description Table 98 System Register Name Base Default System I2C audio master 0x21 Offset: 0x20 System Settings Register This register is reset at a DVDD-POR. Bit 7:4 Bit Name Version <3:0> Default 0010 Access R 3 PVDDp 0 R/W 2 IOVDDp 0 R/W 1 EnWDogPwdn 0 R/W 0 PwrUpHld 1 R/W Bit Description AFE number to identify the design version 0010: revision 2 PVDD trimming: 0: Vnom 1: Vnom *17/18 IOVDD trimming: 0: IOVDD = 3.11V (nominal) 1: IOVDD = 2.94V 0: forced power down through watchdog is disabled 1: forced power down through watchdog is enabled (no serial interface reading within 1s) 0: power up hold is cleared and supply is switched off 1: set to on after power on © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 120 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.2 7.4.2.1 • • • • • • • • • • • • 3V Step-Up Converter General Output voltage 3V to 3.6V (BVDD) programmable in 4 steps via DCDC3p bit to save power Input voltage 1V (1.2V) to 3V, voltages higher than that can be connected to BVDD directly Maximum output current to BVDD: 150mA Current mode operation On-chip compensation and feedback network On chip 300mΩ NMOS switch PWM mode with 1.2MHz switching frequency Inductor current limitation 850mA Pulse skipping capability Low quiescent current: 40μA in PFM-mode, 300μA in PWM mode ≤1μA shutdown current uses external coil (6.8μH) and Schottky diode (500mA) Figure 45 DCDC 3V Block Diagram 7.4.2.2 Parameter Table 99 DCDC Boost Parameter Symbol I VDD2.9 Parameter Supply Current V STARTUP V HOLD R SW_on f SW Startup Voltage Hold-on Voltage Internal Switch R DS_ON Switching Frequency t ON_min t OFF_min η eff Minimum On-time Minimum Off-time Efficiency I SW_LIM I OUT Current Limit Load Current Notes Power down mode PFM mode operation PWM mode (low output load) R Load >220Ω I OUT =1mA, VBAT falling from 1.5 to 0V Start-up, X3VOK=1 PWM mode operation, X3VOK=0 I OUT =20mA, Vin=1.35 I OUT =50mA, Vin=1.5 1.0V ≤ VB1V ≤ 3.0V VB1V=1.0V Min Typ Max Unit 5 μA μA μA V V mΩ kHz MHz ns ns % % A mA 40 300 1.0 0.5 100 0.60 250 1.2 100 100 85 87 0.85 300 500 1.10 150 Vin=1.0..2.0V, C(VBAT_1V) = 2.2μF ceramic || 2000μF Elko, C(BVDD) = 3 x 2.2μF ceramic, L=DS1608 6.8μH, Temp = 25deg © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 121 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Figure 46 DCDC Boost Typical Performance Characteristics 90,0 85,0 Eff. [%] 80,0 1,5V 1,35V 1,25V 1,1V 0,9V 75,0 70,0 65,0 60,0 1 10 100 1000 Iout [mA] BVDD=3.1V, L=DS1608 6.8μH, Temp = 25deg 7.4.2.3 Register Description Table 100 CVDD / DCDC3 Register Name Base Default CVDD / DCDC 3 I2C audio master 0x00 Offset: 0x21 Charge Pump and 3V DCDC Register This register is reset at a DVDD-POR. Bit 7 Bit Name CP_SW Default Access 0 R/W 6 CP_on 0 R/W 5 LREG_CPnot 0 R W 4:3 DCDC3p 00 R/W 2 LREG_off 0 R/W 1:0 CVDDp 00 R/W Bit Description charge pump / length regulator switch margin reduction 0: margin set to 200/300 mV 1: margin reduced to 150/225 mV (automatic switching to length regulator is done “later”, at a lower input voltage) 0: normal operation 1: keeps Mode 3 charge pump always on Please note that bit 2 = “0”, overrides bit 6. Core voltage generation mode 0: CP is working 1: LREG is working For production testing purpose only, in normal application mode this bit must always be written with “0”. DCDC3 Vout programming (BVDD) 00: 3.6V 01: 3.2V 10: 3.1V 11: 3.0V 0: keeps Mode2 (length regulator always on) 1: normal operation CVDD trimming: 00: 1.2V 01: 1.15V 10: 1.10V 11: 1.05V © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 122 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.3 7.4.3.1 Low Drop Out Regulators General These LDO’s are designed to supply sensitive analogue circuits, audio devices, AD and DA converters, micro-controller and other peripheral devices. The design is optimised to deliver the best compromise between quiescent current and regulator performance for battery powered devices. Stability is guaranteed with ceramic output capacitors of 1μF +/-20% (X5R) or 2.2μF +100/-50% (Z5U). The low ESR of these caps ensures low output impedance at high frequencies. Regulation performance is excellent even under low dropout conditions, when the power transistor has to operate in linear mode. Power supply rejection is high enough to suppress high ripple on the battery at the output. The low noise performance allows direct connection of noise sensitive circuits without additional filtering networks. The low impedance of the power device enables the device to deliver up to 150mA even at nearly discharged batteries without any decrease of performance. Figure 47 LDO Block Diagram 7.4.3.2 LDO1 This LDO generates the analog supply voltage used for the AFE itself. • • Input voltage is BVDD Output voltage is AVDD (typ. 2.9V) 7.4.3.3 LDO2 This LDO generates the digital supply voltage used for the AFE itself. • • • Input Voltage is BVDD Output Voltage is DVDD (typ. 2.9V) Driver strength: 200mA 7.4.3.4 LDO3 This LDO can used to generate the periphery voltage for the digital processor (e.g. vdd_mem for MPMC interface) • • • • Input Voltage BVDD Output Voltage is PVDD 1.7 to 3.3V Driver strength: 200mA Programmable via P_PVDD pin and PVDDp bit in 8 steps Table 101 PVDD programming P_PVDD VSS 150k to VSS Open 150k to DVDD DVDD PVDDp=0 PVDDp=1 OFF 2.50V 3.33V 2.90V 1.80V OFF 2.36V 3.15V 2.74V 1.70V © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 123 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.3.5 LDO4 This LDO will be used to supply the digital processor periphery (vdd_peri). Default value is 3.11V, but it can be manually programmed to 2.94V if needed. • • • • Input Voltage BVDD Output Voltage is IOVDD (3.11 or 2.94) Programmable via IOVDDp bit. Driver strength: 200mA 7.4.3.6 LDO6 This LDO will be used to supply the USB 2.0 OTG interface block. • • • • Input Voltage BVDD Output Voltage is UVDD (3.26V) separate enable bit in USB_UTIL register (0x17) Driver strength: 200mA 7.4.3.7 Parameter Table 102 LDOs Block Characteristics Symbol Parameter R ON PSRR On resistance Power supply rejection ratio I OFF I VDD Noise t start V out Shut down current Supply current Output noise Startup time Output voltage V out_tol V LineReg Output voltage tolerance Line regulation V LoadReg Load regulation I LIMIT Current limitation Notes f=1kHz f=100kHz Min Typ LDO1, LDO1, LDO1, LDO1, LDO1, Static Transient; Slope: t r =10μs Static Transient; Slope: t r =10μs LDO2, LDO3, LDO4 Unit 1 Ω dB 100 50 50 200 2.85 3.56 nA μA μV rms μs V V V mV mV 70 40 without load 10Hz < f < 100kHz Vbat>3.0V full prog. range LDO1, LDO2 Max 1.7 1.7 2.9 -50 -1 -10 -1 -10 50 1 10 1 10 400 mV mA BVDD=4V; ILOAD=150mA; Tamb=25ºC; CLOAD =2.2μF (Ceramic); unless otherwise specified © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 124 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.3.8 Register Description Table 103 System Register Name Base Default System I2C audio master 0x21 Offset: 0x20 System Settings Register This register is reset at a DVDD-POR. Bit 7:4 Bit Name Version <3:0> Default 0010 Access R 3 PVDDp 0 R/W 2 IOVDDp 0 R/W 1 EnWDogPwdn 0 R/W 0 PwrUpHld 1 R/W Bit Description AFE number to identify the design version 0010: revision 2 PVDD trimming: 0: Vnom 1: Vnom *17/18 IOVDD trimming: 0: IOVDD = 3.11V (nominal) 1: IOVDD = 2.94V 0: forced power down through watchdog is disabled 1: forced power down through watchdog is enabled (no serial interface reading within 1s) 0: power up hold is cleared and supply is switched off 1: set to on after power on Table 104 USB_UTIL Register Name Base Default USB_UTIL I2C audio master 0x00 Offset: 0x17 Bit 7..5 4 Bit Name USB Utility Register This register is reset at a DVDD-POR. LDO6_on Default 000 0 Access n/a R/W 3:2 COMP_TH<1:0> 0 R/W 1 SKIP_ENAB 0 R/W 0 CP_5V_on 0 R/W Bit Description 0: UVDD generation disabled 1: LDO6 for generating UVDD enabled. Sets the threshold for the VBUS comparator 00: 4.5V 01: 3.18V 10: 1.5V 11: 0.6V 0: normal operation 1: enables the skip mode for the VBUS 1:2 charge pump. This is increasing the efficiency for smaller loads, but increasing the VBUS ripple. 0: disables VBUS charge pump 1: enables VBUS charge pump © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 125 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.4 7.4.4.1 Charge-Pump Step-Down Converter General This converter will be used to supply the core voltage for a microprocessor. • • • • • • • Input Voltage CPVDD Output Voltage 1.05 to 1.2 V Voltage setting via CVDDp<1:0> bits in 4 steps regulated 2:1 charge pump with pulse skipping scaleable switches according to BVDD Bypass LDO for higher currents or lower battery voltages respectively Driver strength: 50mA / 200mA with bypass LDO Figure 48 CP Block Diagram 7.4.4.2 Mode Description Three different functional parts generate core supply voltage CVDD. The switching between the modes is generally done automatically, but can also be manually overwritten by register settings. Please observe that the charge pump block starts up in Mode 2(IOVDD length regulator mode) to avoid a current limitation and has to be switched to automatic operation by register settings. Direct length regulation from VBAT Mode1=true IF ((1.2V+Vmargin1) < VBAT_1V < (VTH1)) && (NoUSB) • • • • Vmargin1=50mV/150mV (100mV hysteretic) VTH1=1.7V/1.8V (100mV hysteretic) VBAT LDO is used when [1.8V > VBAT_1V > 1.25V] VBAT LDO is not used when there is high supply present from USB even when VBAT is in range. Direct length regulation from IOVDD Mode2=true IF ((Not Mode1) && (IOVDD/2 < (1.2+Vmargin2))) • • • Vmargin2=200mV/300mV (100mV hysteretic) IOVDD LDO is used when VBAT LDO Mode1 is not entered and IOVDD is not high enough to do 2:1 charge-pump regulation. Charge-Pump IOVDD division by 2 active plus length regulation Mode3=true IF ((Not Mode1) && (Not Mode2)) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 126 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.4.3 Parameter Table 105 CP Typical Performance Parameter CVDD Charge Pump Regulation to 1.2V 1,3 V_CVDD [V] 1,25 1,2 1,15 h 1,1 BVDD= 2.8V BVDD= 3.0V BVDD= 3.2V BVDD= 3.6V BVDD= 3.4V 1,05 0 50 100 150 200 250 I_CVDD [mA] CVDD Lengh Regulation to 1.2V BVDD= 3.6V 1,25 BVDD= 3.4V V_CVDD [V] 1,2 1,15 1,1 BVDD= 3.0V 1,05 BVDD= 3.2V 1 0 50 100 150 200 250 300 350 400 I_CVDD [mA] © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 127 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.4.4 Register Settings Table 106 CVDD / DCDC3 Register Name Base Default CVDD / DCDC 3 I2C audio master 0x00 Offset: 0x21 Charge Pump and 3V DCDC Register This register is reset at a DVDD-POR. Bit 7 Bit Name CP_SW 0 Default R/W Access 6 CP_on 0 R/W 5 LREG_CPnot 0 R W 4:3 DCDC3p 00 R/W 2 LREG_off 0 R/W 1:0 CVDDp 00 R/W Bit Description charge pump / length regulator switch margin reduction 0: margin set to 200/300 mV 1: margin reduced to 150/225 mV (automatic switching to length regulator is done “later”, at a lower input voltage) 0: normal operation 1: keeps Mode 3 charge pump always on Please note that bit 2 = “0”, overrides bit 6. Core voltage generation mode 0: CP is working 1: LREG is working For production testing purpose only, in normal application mode this bit must always be written with “0”. DCDC3 Vout programming (BVDD) 00: 3.6V 01: 3.2V 10: 3.1V 11: 3.0V 0: keeps Mode2 (length regulator always on) 1: normal operation CVDD trimming: 00: 1.2V 01: 1.15V 10: 1.10V 11: 1.05V © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 128 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.5 7.4.5.1 Audio Line Output General The line output is designed to provide the audio signal with typical 1Vp at a load of minimum 10kΩ, which is a minimum value for line inputs. Additional this output amplifier is capable to drive a 32Ω load (e.g. an earpiece of a mobile phone). To achieve this operation mode can be switched from single ended stereo to mono differential. This output stage has an independent gain regulation for left and right channel with 32 steps @ 1.5dB each. The gain can be set from -40.5dB to +6dB. Changing of volume and mute control can only be done after enabling the output. If using the output in mono differential mode, the volume setting for the right channel should be set to 0dB. Figure 49 Line Output Stereo Mode 7.4.5.2 Mono Differential Mode (please observe that gain of right channel amplifier has to best to 0dB) Parameter Table 107 Line Output Characteristics Symbol RL Parameter Output Load A0 Gain Ax Gain Step-Size SNR Signal to Noise Ratio Notes Min Typ Max Unit stereo mode 10k Ohm differential mode 32 Ohm programmable gain -40.5 6 1.5 stereo mode Mute Attenuation dB dB 90 dB 120 dB BVDD = 3.3V, TA= 25oC unless otherwise mentioned © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 129 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.5.3 Register Description Table 108 Line Output Related Register Name AudioSet_1 Base I2C audio master Offset 0x14 Description Enable/disable driver stage Table 109 LINE_OUT_R Register Name Base Default LINE_OUT_R I2C audio master 0x00 Offset: 0x00 Bit 7:5 4:0 Bit Name LOR_VOL Right Line Output Register This register is reset when the block is disabled in AudioSet1 register (0x14) or at a DVDD-POR. The register cannot be written when the block is disabled. Default 000 00000 Access n/a R/W Bit Description do not change volume settings for right line output, adjustable in 32 steps @ 1.5dB 11111: 6 dB gain 11110: 4.5 dB gain .. 00001: -39 dB gain 00000: -40.5 dB gain Table 110 LINE_OUT_L Register Name Base Default LINE_OUT_L I2C audio master 0x00 Offset: 0x01 Left Line Output Register This register is reset when the stage is disabled in AudioSet1 register (0x14) or at a DVDD-POR. The register cannot be written when the block is disabled. Bit 7:6 Bit Name LO_SES_DM Default 00 Access R/W 5 4:0 LOL_VOL 0 00000 n/a R/W Bit Description Single ended stereo or differential mono selection 11: do not use 10: output switched to single ended stereo 01: output switched to differential mono 00: output switched to mute do not change volume settings for right line output, adjustable in 32 steps @ 1.5dB 11111: 6 dB gain 11110: 4.5 dB gain .. 00001: -39 dB gain 00000: -40.5 dB gain © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 130 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.6 7.4.6.1 Headphone Output General The headphone output is designed to provide the audio signal with 2x40mW @ 16Ω or 2x20mW @32Ω, which are typical values for headphones. This output stage has an independent gain regulation for left and right channel with 32 steps @ 1.5dB each. The gain can be set from –43.43dB to +1.07dB. The maximum output power of 40mW @ 16Ω is achieved, by setting the mixer output to 1Vp and using the gain of 1.07dB. Figure 50 Headphone Output Headphones connected via decoupling capacitors 7.4.6.2 Headphones connected to Phantom Ground (Common Mode) Phantom Ground HPCM pin is the buffered HPGND output. It can be used to drive the loads without external blocking capacitors between HPL / HPR and HPCM. If the load is between HPR / HPL and BVSS, 100uF of de-coupling capacitors are needed. The phantom ground can be switched off to save power if not needed. 7.4.6.3 No-Pop Function To avoiding click and pop noise during power-up and shutdown, the output is automatically set to mute when the output stage is disabled. HPGND pin, which needs a 100nF capacitor outside, gets charged on power-up with 2uA to AGND=1.45V. After start-up the DC level of the following pins are the same: HPR=HPL=HPCM=HPGND=AGND=1.45V. The Start-up time before releasing mute is about 90ms. To avoid popnoise 150ms discharging time of HPGND after a shutdown, have to be waited before starting up again. 7.4.6.4 Over-current Protection This output stage has an over-current protection, which disables the output for 256ms or 512ms. This value can be set in the headphone registers. The over-current protection limit of HPR and HPL pin is typical 145mA while HPCM pin has a 210mA threshold. If needed, the over-current condition can also be signalled via an interrupt to the controlling microprocessor. 7.4.6.5 Headphone Detection With a control bit the headphone detection can be enabled. The detection is only working as long as the headphone stage is in power down mode and the load is applied between HPR / HPL and HPCM. The headphone detection can also trigger a corresponding interrupt. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 131 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.6.6 Power Save Options To save power, especially when driving 32 Ohm loads, a reduction of the bias current can be selected. Together with switching off the phantom ground this gives 4 possible operating modes. Table 111 Headphone Power-Save Options HPCM_OFF 0 1 0 1 IBR_HPH 0 0 1 1 IDD_HPH (typ.) 2.2mA 1.5mA 1.5mA 1.0mA Load 16 Ohm 16 Ohm 32 Ohm 32 Ohm BVDD = 3.3V, TA= 25oC unless otherwise mentioned 7.4.6.7 Parameter Table 112 Power Amplifier Block Characteristics Symbol Parameter RL Output Load Pout Maximum Output Power A0 Ax PSRR I OUT_pd T power_up SNR Notes stereo mode R L = 32Ω R L = 16Ω programmable gain Gain Gain Step-Size Power Supply Rejection Ratio 200Hz-20kHz, 720mVpp, R L = 16Ω Short Current Protection Level I OUT power down Min 16 Typ Max 20 40 -43.43 60 1.07 1.5 90 145 -20 20 90 Signal to Noise Ratio Mute Attenuation 90 120 Unit Ohm mW mW dB dB dB mA uA ms dB dB BVDD = 3.3V, TA= 25oC unless otherwise mentioned © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 132 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.6.8 Register Description Table 113 Headphone Related Register Name AudioSet_3 IRQ_ENRD_1 Base I2C audio master I2C audio master Offset 0x16 0x26 Description Power save options, common mode buffer Interrupt settings for over current and HP detection Table 114 HPH_OUT_R Register Name Base Default HPH_OUT_R I2C audio master 0x00 Offset: 0x02 Right Headphone Output Register This register is reset at a DVDD-POR. Bit 7:6 Bit Name HP_OVC_TO Default 00 Access R/W 5 4:0 HPR_VOL 0 00000 n/a R/W Bit Description headphone over current time out: 11: 0 ms 10: 512 ms 01: 128 ms 00: 256 ms do not change volume settings for right headphone output, adjustable in 32 steps @ 1.5dB 11111: 1.07 dB gain 11110: -0.43 dB gain .. 00001: -43.93 dB gain 00000: -45.43 dB gain Table 115 HPH_OUT_L Register Name Base Default HPH_OUT_L I2C audio master 0x00 Offset: 0x03 Left Headphone Output Register This register is reset at a DVDD-POR. Bit 7 Bit Name HP_Mute_on 0 Default Access R/W 6 HP_on 0 R/W 5 HPdet_on 0 R/W 4:0 HPL_VOL 00000 R/W Bit Description 0: normal operation 1: headphone output set to mute (mute is on during power-up) 0: headphone stage not powered 1: power up headphone stage 0: no headphone detection 1: enable headphone detection volume settings for left headphone output, adjustable in 32 steps @ 1.5dB 11111: 1.07 dB gain 11110: -0.43 dB gain .. 00001: -43.93 dB gain 00000: -45.43 dB gain © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 133 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.7 7.4.7.1 Speaker Output General The speaker output is designed to provide the stereo audio signal with 2x500mW @ 4Ω. This output stage has an independent gain regulation for left and right channel with 32 steps @ 1.5dB each. The gain can be set from −40.5dB to +6dB. The maximum output power of 500mW @ 4Ω is achieved, by setting the mixer output to 1Vp and using the gain of +6dB. Figure 51 Speaker Output Speaker connected via decoupling capacitors 7.4.7.2 Latchup Protection For latchup protection of pins LSPL and LSPR, external schottky diodes must be implemented from LSPL to BVDD and LSPR to BVDD as drawn in the above diagram. These diodes protect pins LSPL and LSPR against the back-voltage induced by the inductance of the speaker in case of switching off the speaker. These diodes must be schottky type diodes with low forward voltages to prevent high current through the internal LSPR/LSPL ESD protection diodes that potentially would cause latchup for currents exceeding the maximum input current specifications given in chapter 6.1 Absolute Maximum Ratings. These schottky diodes must be capable of surging maximum peak currents of up to 600 mA. 7.4.7.3 No-Pop Function BGND pin, which needs a 100nF capacitor outside, gets charged on power-up to BVDD/2.To avoiding click and pop noise during power-up and shutdown, the output is automatically set to mute when the output stage is disabled. The Start-up time before releasing mute is about 100ms. To avoid pop-noise the 150ms discharging time of SPR / SPL after a shutdown (220µF capacitor in stereo single ended mode assumed), have to be waited before starting up again. 7.4.7.4 Over-current Protection This output stage has an over-current protection, which disables the output for 0 to 512ms. This value can be set in the speaker registers. The overcurrent protection limit of SPR and SPL pin is typical 700mA. To get an interrupt on an over-current event, the corresponding bit in the IRQ_ENRD1 register (0x26h) has to be set. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 134 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.7.5 Power Save Options When driving > 4Ω, two power save options can be chosen. The output driver stage can be set to only 25% drive capacity, which will reduce the maximum output power. Additionally the bias currents can be reduced to 50% in 3 steps. Table 116 Speaker Power-Save Options LSP_LP 0 1 1 1 1 IBR_LSP 00 00 01 10 11 IDD_LSP (typ.) 8mA 2.8mA 2.4mA 1.9mA 1.5mA Load 4 Ohm 16-32 Ohm 16-32 Ohm 16-32 Ohm 16-32 Ohm BVDD = 3.3V, TA= 25oC unless otherwise mentioned 7.4.7.6 Parameter Table 117 Speaker Amplifier Parameter Symbol Parameter RL Output Load Pout A0 Ax PSRR I OUT_pd T power_up SNR Notes stereo mode mono differential mode Maximum Output Power R L = 8Ω Gain programmable gain Gain Step-Size Power Supply Rejection Ratio 200Hz-20kHz, 720mVpp, no load Short Current Protection Level I OUT power down Min 4 8 Typ Max 1 -40.5 70 6 1.5 75 700 -20 20 100 Signal to Noise Ratio Mute Attenuation 90 120 Unit Ohm Ohm W dB dB dB mA uA ms dB dB BVDD = 5V, TA= 25oC unless otherwise mentioned © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 135 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.7.7 Register Description Table 118 Speaker Related Register Name AudioSet_2 IRQ_ENRD_1 Base I2C audio master I2C audio master Offset 0x15 0x26 Description Power save options Interrupt settings for over current detection Right Speaker Register (04h) Table 119 LSP_OUT_R Register Name Base Default LSP_OUT_R I2C audio master 0x00 Offset: 0x04 Right Speaker Output Register This register is reset at a DVDD-POR. Bit 7:6 Bit Name SP_OVC_TO Default 00 Access R/W 5 4:0 SPR_VOL 0 00000 n/a R/W Bit Description speaker over current time out: 11: 0 ms 10: 512 ms 01: 128 ms 00: 256 ms do not change volume settings for right speaker output, adjustable in 32 steps @ 1.5dB 11111: 6 dB gain 11110: 4.5 dB gain .. 00001: -39 dB gain 00000: -40.5 dB gain © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 136 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 120 LSP_OUT_L Register Name Base Default SPH_OUT_L I2C audio master 0x00 Offset: 0x05 Left Speaker Output Register This register is reset at a DVDD-POR. Bit 7 Bit Name SP_Mute_on Default 0 Access R/W 6 SP_on 0 R/W 5 4:0 SPL_VOL 0 00000 n/a R/W Bit Description 0: normal operation 1: speaker output set to mute (mute is on during power-up) 0: speaker stage not powered 1: power up speaker stage do not change volume settings for left speaker output, adjustable in 32 steps @ 1.5dB 11111: 6 dB gain 11110: 4.5 dB gain .. 00001: -39 dB gain 00000: -40.5 dB gain © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 137 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.8 7.4.8.1 Microphone Inputs (2x) General The chip features two identical microphone inputs. The blocks have differential inputs to a microphone amplifier with adjustable gain. This stage also includes an AGC. The following volume control has an independent gain regulation for left and right channel with 32 steps @ 1.5dB each. The gain can be set from – 40.5dB to +6dB. The stage is set to mute by default. If the microphone input is not enabled, the volume settings are set to their default values. Changing of volume and mute control can only be done after enabling the input. Figure 52 Microphone Input Microphone Preamplifier and Gain Stage 7.4.8.2 AGC The microphone amplifier includes an AGC, which is limiting the signal to 1Vp. The AGC has 15 steps with a dynamic range of about 29dB. The AGC is ON by default but can be disabled by a microphone register bit. 7.4.8.3 Supply & Detection Each microphone input generates a supply voltage of 1.5V above HPHCM. The supply is designed for ≤2mA and has a 10mA current limit. In OFF mode the MICSUP terminal is pulled to AVDD with 30kohm. A current of typically 50uA generates an interrupt to inform the CPU, that a circuit is connected. When using HPHCM as headset ground the HPH–stage gives the interrupt. After enabling the HPH-stage through the CPU the microphone detection interrupt will follow. 7.4.8.4 Remote Control Fast changes of the supply current of typically 500uA are detected as a remote button press, and an interrupt is generated. Then the CPU can start the measurement of the microphone supply current with the internal 10-bit ADC to distinguish which button was pressed. As the current measurement is done via an internal resistor, only two buttons generating a current of about 0.5mA and 1mA can be detected. With this 1mA as microphone bias is still available. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 138 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.8.5 Parameter Table 121 Microphone Inputs Parameter Symbol Parameter A0 Ax R inMIC A MIC 0 A MIC 1 A MIC 2 Gain Gain Step-Size Input Resistance MicAmp_Gain0 MicAmp_Gain1 MicAmp_Gain2 SoftClip_AGC_Range Attack_Time Release_Time V Innom 0 Nominal_Input_Voltage0 V Innom 1 Nominal_Input_Voltage1 V Innom 2 Nominal_Input_Voltage2 SNR Signal to Noise Ratio Mute Attenuation Microphone Supply V MICsup Microphone Supply Voltage I MIClim Mic. Supply Current Limit I MICdet Mic. Detection Current I REMdet Remote Detection Current V noise Voltage Noise BVDD = 3.3V, TA= 25oC Notes programmable gain Min Typ Max Unit 6 dB dB kOhm dB dB dB dB us ms mVp mVp mVp dB dB -40.5 1.5 15 28 34 40 15*2.0 60 120 40 20 10 differential MicInGain = 0dB, MicAmp_Gain0 MicInGain = 0dB, MicAmp_Gain1 MicInGain = 0dB, MicAmp_Gain2 90 120 0-4mA microphone supply current step 2.95 10 50 500 5.7 V mA uA uA uV unless otherwise mentioned © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 139 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.8.6 Register Description Table 122 Microphone Related Register Name AudioSet_1 IRQ_ENRD_1 IRQ_ENRD_2 Base I2C audio master I2C audio master I2C audio master Offset 0x14 0x26 0x27 Description Enable/disable driver stage Interrupt settings for microphone detection Interrupt settings for remote button press detection Table 123 MIC1_R & MIC2_R Register Name Base Default MIC1_R, MIC2_R I2C audio master 0x00 Offset: 0x06, 0x08 Bit 7 6:5 4:0 Bit Name Mic1_AGC_off Mic2_AGC_off Mic1_Gain Mic2_Gain Mic1R_VOL Mic2R_VOL Right Microphone Input Registers This register is reset when the block is disabled in AudioSet1 register (0x14) or at a DVDD-POR. The register cannot be written when the block is disabled. Default 0 Access R/W 00 R/W 00000 R/W Bit Description 0: automatic gain control enabled 1: automatic gain control disabled 00: gain set to 28 dB 01: gain set to 34 dB 10: gain set to 40 dB 11: reserved, do not use. volume settings for right microphone input, adjustable in 32 steps @ 1.5dB 11111: 6 dB gain 11110: 4.5 dB gain .. 00001: -39 dB gain 00000: -40.5 dB gain Table 124 MIC1_L & MIC2_L Register Name Base Default MIC1_L, MIC2_L I2C audio master 0x00 Offset: 0x07, 0x09 Bit 7 6 5 4:0 Bit Name Mic1_Sup_off Mic2_Sup_off Mic1_Mute_off Mic2_Mute_off Mic1L_VOL Mic2L_VOL Left Microphone Input Registers This register is reset when the block is disabled in AudioSet1 register (0x14) or at a DVDD-POR. The register cannot be written when the block is disabled. 0 Default Access R/W 0 R/W 0 00000 n/a R/W Bit Description 0: microphone supply enabled 1: microphone supply disabled 0: microphone input set to mute 1: normal operation volume settings for left microphone input, adjustable in 32 steps @ 1.5dB 11111: 6 dB gain 11110: 4.5 dB gain .. 00001: -39 dB gain 00000: -40.5 dB gain © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 140 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.9 7.4.9.1 Audio Line Inputs (2x) General The chip features includes two identical line inputs. The blocks can work in mono differential, 2x mono single ended or in stereo single ended mode. The volume control has an independent gain regulation for left and right channel with 32 steps @ 1.5dB each. The gain can be set from –34.5dB to +12dB. The stage is set to mute by default. If the line input is not enabled, the volume settings are set to their default values. Changing the volume and mute control can only be done after enabling the input. Figure 53 Line Inputs Stereo Mode Mono Single Ended Mode Mono Differential Mode 7.4.9.2 Parameter Figure 54 Line Input Parameter Symbol Parameter A0 Ax R inLINE Gain Gain Step-Size Input Resistance SNR Signal to Noise Ratio Mute Attenuation Notes programmable gain Min Typ -34.5 Max Unit 12 dB dB kOhm kOhm dB dB 1.5 49 100 Mute Min Gain, single ended stereo 90 120 BVDD = 3.3V, TA= 25oC, fs=48kHz unless otherwise mentioned © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 141 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.9.3 Register Description Table 125 Line Input Related Register Name AudioSet1 Base I2C audio master Offset 0x14 Description Enable/disable driver stage Table 126 LINE_IN1_R & LINE_IN2_R Register Name Base Default LINE_IN1_R, LINE_IN2_R I2C audio master 0x00 Offset: 0x0A, 0x0C Bit 7:6 5 4:0 Bit Name LI1R_Mute_off LI2R_Mute_off LI1R_VOL LI2R_VOL Right Line Input Registers This register is reset when the block is disabled in AudioSet1 register (0x14) or at a DVDD-POR. The register cannot be written when the block is disabled. Default 00 0 Access n/a R/W 00000 R/W Bit Description do not change 0: right line input is set to mute 1: normal operation volume settings for right line input, adjustable in 32 steps @ 1.5dB 11111: 12 dB gain 11110: 10.5 dB gain .. 00001: -33 dB gain 00000: -34.5 dB gain Table 127 LINE_IN1_L & LINE_IN2_L Register Name Base Default LINE_IN1_L, LINE_IN2_L I2C audio master 0x00 Offset: 0x0B, 0x0D Right Line Input Registers This register is reset when the block is disabled in AudioSet1 register (0x14) or at a DVDD-POR. The register cannot be written when the block is disabled. Bit 7:6 Bit Name LI1_Mode LI2_Mode Default 00 Access R/W 5 LI1L_Mute_off LI2L_Mute_off LI1L_VOL LI2L_VOL 0 R/W 00000 R/W 4:0 Bit Description Stereo or mono input selection 00: inputs switched to single ended stereo 01: inputs switched to differential mono 10: inputs switched to single ended mono 11: reserved, do not use. 0: left line input is set to mute 1: normal operation volume settings for right line input, adjustable in 32 steps @ 1.5dB 11111: 12 dB gain 11110: 10.5 dB gain .. 00001: -33 dB gain 00000: -34.5 dB gain © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 142 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.10 I2S Digital Audio Interface 7.4.10.1 Input Digital audio data can be fed into the AS3515A via the I2S interface These input data are then used by the 18-bit DAC to generate the analog audio signal. The volume control has an independent gain regulation for left and right channel with 32 steps @ 1.5dB each. The gain can be set from –40.5dB to +6dB. The stage is set to mute by default. If the DAC input is not enabled, the volume settings are set to their default values. Changing the volume and mute control can only be done after enabling the input. 7.4.10.2 Output This block consists of an audio multiplexer where the signal, which should be recorded, can be selected. The output is then fed through a volume control to the 14 bit ADC. The digital output is done via an I2S interface. The volume control has an independent gain regulation for left and right channel with 32 steps @ 1.5dB each. The gain can be set from –34.5dB to +12dB. The stage is set to mute by default. If the ADC output is not enabled, the volume settings are set to their default values. Changing the volume and mute control can only be done after enabling the input. The I2S output uses the same clocks as the I2S input. The sampling rate therefore depends also on the input sampling rate. 7.4.10.3 Signal Description The digital audio interface uses the standard I2S format: • left justified • MSB first • one additional leading bit The first 18 bits are taken for DAC conversion. The on-chip synchronization circuit allows any bit-count up 32bit. When there are less than 18 bits sampled, the data sample is completed with “0”s. The ADC output is always 16 bit. If more SCLK pulses are provided, only the first 16 will be significant. All following bits will be “0”. SCLK has not to be necessarily synchronous to LRCK but the high going edge has to be separate from LRCK edges. The LRCK signal has to be derived from a jitter-free clock source, because the on-chip PLL is generating a clock for the digital filter, which has to be always in correct phase lock condition to the external LRCK. The digital part has to provide MCLK (master clock) with 128*fs (fs = audio sampling frequency) over-sampling to guarantee a proper DAC and ADC operation. Figure 55 I2S Left Justified Mode © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 143 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Figure 56 I2S Timing 7.4.10.4 Power Save Options The bias current of the DAC block can be reduced in three steps down to 50% to reduce the power consumption. 7.4.10.5 Clock Supervision The digital audio interface automatically checks the LRCK. An interrupt can be generated when the state of the LRCK input changes. A bit in the interrupt register represents the actual state (present or not present) of the LRCK. 7.4.10.6 Parameter Table 128 Audio Converter Parameter Symbol A0 Parameter Gain Gain Step-Size Mute Attenuation I2S inputs / outputs V IL V IH V OL V OH T SCLKH SCLK clock high time T SCLKL SCLK clock low time T SDSU Data set-up time T SDHD Data hold time T SDOD Data Output Delay T LRSU Clock set up time T LRHD Clock hold time T S1, T S2 Clock separation time T JITTER clock Jitter Notes programmable gain DAC input programmable gain ADC output Min Typ -43.43 -34.5 Max Unit 1.07 12 dB dB dB dB 0.42 DVDD 0.3 - V V V V ns ns ns ns ns ns ns ns ns 1.5 Ax 120 SCLK, LRCK, SDI (30%DVDD/2) SCLK, LRCK, SDI (70%DVDD/2) SDO,IRQ @2mA SDO,IRQ @2mA SDI versus rising edge of SCLK SDI versus rising edge of SCLK SDO versus falling edge of SCLK LRCK versus rising edge of SCLK LRCK versus rising edge of SCLK MCLCK rising edge versus LRCK LRCK 1.02 2.6 80 80 80 80 - 25 80 80 20 -20 20 BVDD = 3.3V, DVDD = 2.9V, TA= 25oC unless otherwise mentioned © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 144 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.10.7 Register Description Table 129 Audio Converter Related Register Name AudioSet_1 AudioSet_2 IRQ_ENRD_1 Base I2C audio master I2C audio master I2C audio master Offset 0x14 0x15 0x25 Description Enable/disable DAC and ADC Power save options and dither control Interrupt settings for LRCK changes Table 130 DAC_R Register Name Base Default DAC_R I2C audio master 0x00 Offset: 0x0E Bit 7:5 4:0 Bit Name DAR_VOL Right DAC output Registers This register is reset when the block is disabled in AudioSet1 register (0x14) or at a DVDD-POR. The register cannot be written when the block is disabled. Default 000 00000 Access n/a R/W Bit Description do not change volume settings for right DAC output, adjustable in 32 steps @ 1.5dB 11111: 6 dB gain 11110: 4.5 dB gain .. 00001: -39 dB gain 00000: -40.5 dB gain Table 131 DAC_L Register Name Base Default DAC_L I2C audio master 0x00 Offset: 0x0F Left DAC output Registers This register is reset when the block is disabled in AudioSet1 register (0x14) or at a DVDD-POR. The register cannot be written when the block is disabled. Bit 7 6 Bit Name Default DAC_Mute_off 0 0 Access n/a R/W 5 4:0 DAL_VOL 0 00000 n/a R/W Bit Description 0: DAC output is set to mute 1: normal operation volume settings for left DAC output, adjustable in 32 steps @ 1.5dB 11111: 6 dB gain 11110: 4.5 dB gain .. 00001: -39 dB gain 00000: -40.5 dB gain © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 145 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 132 ADC_R Register Name Base Default ADC_R I2C audio master 0x00 Offset: 0x10 Right ADC input Registers This register is reset when the block is disabled in AudioSet1 register (0x14) or at a DVDD-POR. The register cannot be written when the block is disabled. Bit 7:6 Bit Name ADCmux Default 00 Access R/W Bit Description 00: Stereo Microphone 01: Line_IN1 10: Line_IN2 11: Audio SUM 5 4:0 ADR_VOL 00000 R/W volume settings for right ADC input, adjustable in 32 steps @ 1.5dB 11111: 12 dB gain 11110: 10.5 dB gain .. 00001: -33 dB gain 00000: -34.5 dB gain Table 133 ADC_L Register Name Base Default ADC_L I2C audio master 0x00 Offset: 0x11 Left ADC input Registers This register is reset when the block is disabled in AudioSet1 register (0x14) or at a DVDD-POR. The register cannot be written when the block is disabled. Bit 7 Bit Name AD_FS_4 0 Default Access R/W 6 ADC_Mute_off 0 R/W 5 4:0 ADL_VOL 0 00000 n/a R/W Bit Description Divider selection for ADC sampling clock 0: ADC sample clock is I2S LRCK / 2 1: ADC sample clock is I2S LRCK / 4 0: ADC output is set to mute 1: normal operation volume settings for left ADC input, adjustable in 32 steps @ 1.5dB 11111: 12 dB gain 11110: 10.5 dB gain .. 00001: -33 dB gain 00000: -34.5 dB gain © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 146 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.11 Audio Output Mixer 7.4.11.1 General The mixer stage sums up the audio signals of the following stages • Microphone Input 1 • Microphone Input 2 • Line Input 1 • Line Input 2 • Digital Audio Input (DAC) The mixing ratios have to be with the volume registers of the corresponding input stages. Please be sure that the input signals of the mixer stage are not higher than 1Vp. If summing up several signals, each individual signal has of course to be accordingly lower. This shall insure that the output signal is also not higher than 1Vp to get a proper signal for the output amplifier. This stage features an automatic gain control (AGC), which automatically avoids clipping. 7.4.11.2 Register Description Audio Mixer Related Register Name AudioSet_1 AudioSet_2 Base I2C audio master I2C audio master Offset 0x14 0x15 Description Enable/disable mixer stage Enable/disable AGC The mixer stage has no dedicated registers. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 147 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.12 Audio Settings 7.4.12.1 Register Description Table 134 AudioSet_1 Register Name Base Default AudioSet_1 I2C audio master 0x00 Offset: 0x14 First Audio Set Register This register is reset at a DVDD-POR. Bit 7 Bit Name ADC_on Default 0 Access R/W 6 SUM_on 0 R/W 5 DAC_on 0 R/W 4 LOUT_on 0 R/W 3 LIN2_on 0 R/W 2 LIN1_on 0 R/W 1 MIC2_on 0 R/W 0 MIC1_on 0 R/W Bit Description 0: ADC disabled 1: ADC for recording is enabled 0: Summing / Mixing stage is disabled (no audio output) 1: Summing / Mixing stage is enabled 0: DAC disabled 1: DAC enabled 0: Line output disabled 1: Line output enabled 0: Line input 2 disabled 1: Line input 2 enabled 0: Line input 1 disabled 1: Line input 1 enabled 0: Microphone input 2 disabled 1: Microphone input 2 enabled 0: Microphone input 1 disabled 1: Microphone input 1 enabled Table 135 AudioSet_2 Register Name Base Default AudioSet_2 I2C audio master 0x00 Offset: 0x15 Second Audio Set Register This register is reset at a DVDD-POR. Bit 7 Bit Name BIAS_off 0 Default Access R/W 6 DITH_off 0 R/W 5 AGC_off 0 R/W 4:3 IBR_DAC<1:0> 00 R/W 2 LSP_LP 0 R/W 1:0 IBR_LSP<1:0> 00 R/W Bit Description 0: bias enabled 1: bias disabled, for power saving in non audio mode 0: add dither to the DAC audio stream 1: no dither added 0: automatic gain control for summing stage enabled 1: automatic gain control for summing stage disabled Bias current reduction settings for DAC: 00: 0% 01: 25% 10: 40% 11: 50% Low power mode for speaker output: 0: speaker output driver set for 4Ohm to 16Ohm loads 1: speaker output driver set for 16Ohm or larger loads Bias current reduction settings for speaker output: 00: 0% 01: 17% 10: 34% 11: 50% © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 148 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 136 AudioSet_3 Register Name Base Default AudioSet_3 I2C audio master 0x00 Offset: 0x16 Bit 7:3 2 Bit Name Third Audio Set Register This register is reset at a DVDD-POR. ZCU_off Default 00000 0 Access n/a R/W 1 IBR_HPH 0 R/W 0 HPCM_off 00 R/W Bit Description do not change Zero cross gain update of audio outputs 0: zero cross update enabled 1: zero cross update disabled should be disabled for C21O20 Bias current reduction settings for headphone output: 0: headphone output driver set for 16Ohm load 1: headphone output driver set for 32Ohm load or more Headphone common mode buffer settings: 0: headphone CM buffer is switched on 1: headphone CM buffer is switched off © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 149 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.13 VBUS CP & Comparator 7.4.13.1 General This block will be used to generate VBUS for USB OTG host operation and to read back VBUS voltage levels to support USB OTG protocols. • • • • Input Voltage DVDD Output Voltage 5V (VBUS) regulated 1:2 charge pump with pulse skipping Driver strength: 10mA 7.4.13.2 Register Description Table 137 USB_UTIL Register Name Base Default USB_UTIL I2C audio master 0x00 Offset: 0x17 Bit 7..5 4 Bit Name USB Utility Register This register is reset at a DVDD-POR. LDO6_on Default 000 0 Access n/a R/W 3:2 COMP_TH<1:0> 0 R/W 1 SKIP_ENAB 0 R/W 0 CP_5V_on 0 R/W Bit Description 0: UVDD generation disabled 1: LDO6 for generating UVDD enabled. Sets the threshold for the VBUS comparator 00: 4.5V 01: 3.18V 10: 1.5V 11: 0.6V 0: normal operation 1: enables the skip mode for the VBUS 1:2 charge pump. This is increasing the efficiency for smaller loads, but increasing the VBUS ripple. 0: disables VBUS charge pump 1: enables VBUS charge pump © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 150 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.14 Auxiliary Oscillator 7.4.14.1 General This block is a low power oscillator, which can provide a clock to the digital core. CLK_OUT pad of the AFE is connected to clk_int pad of the digital die. 7.4.14.2 Register Description Table 138 CLOCK_OUT Register Name Base Default CLOCK_OUT I2C audio master 0x00 Offset: 0x1D Bit 7..5 4:3 Bit Name Clock Output Register This register is reset at a DVDD-POR. CLKOUT_mode<1:0> Default 000 00 Access n/a R/W 2:1 CLKOUT_drive<1:0> 00 R/W 0 OSC_pd 0 R/W Bit Description CLKOUT pin frequency divider 00: oscillator frequency direct mode 01: osc freq. divide by 2 10: osc freq. divide by 4 11: OFF CLKOUT pin driver strength adjustment 00: 4mA PushPull 01: 2mA PushPull 10: 1mA PushPull 11: 0.5mA PushPull 0: 24MHz oscillator enabled 1: 24MHz oscillator in power down © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 151 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.15 Charger 7.4.15.1 General This block can be used to charge a 4V Li-Io accumulator. It supports constant current and constant voltage charging modes with adjustable charging currents (50 to 400mA) and maximum charging voltage (3.9 to 4.25V). Figure 57 Charger States 7.4.15.2 Trickle Charge If the battery voltage is below 3V, the charger goes automatically in trickle charge mode with 50mA charging current and 3.9V endpoint voltage. In this mode charging current and voltage are not precise, but provide a charger function also for deep discharged batteries. The temperature supervision is not enabled in trickle charge mode. 7.4.15.3 Temperature Supervision This charger block also features a 15uA supply for an external 100k NTC resistor to measure the battery temperature while charging. If the temperature is too high, an interrupt can be generated. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 152 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.15.4 Parameter Table 139 Charger Parameter Symbol I CHG_trick V CHG_trick I CHG (0-7) Parameter Notes Charging Current (trickle charge) BVDD<=3V, CHG_IN = 5.5V BVDD<=3V, CHG_IN = 4.0V Charger Endpoint Voltage (trickle BVDD<=3V, CHG_IN = 4.4V charge) Charging Current BVDD > 3V V CHG (0-7) Charging Voltage BVDD > 3V, end of charge is true V ON_ABS V ON_REL V OFF_REL V BATEMP_ON V BATEMP_OFF I CHG_OFF Charger On Voltage IRQ Charger On Voltage IRQ Charger Off Voltage IRQ Battery Temp. high level (55°C) Battery Temp. low level (50°C) End Of Charge current level BVDD = 3V CHG_IN-CHG_OUT CHG_IN-CHG_OUT BVDD >3V BVDD >3V BVDD >3V Reverse current shut down BVDD = 5V, CHG_IN open I REV_OFF Min Typ Max Unit 37 68 111 17 32 55 0.70* 0.72* 0.74* CHG_IN CHG_IN CHG_IN I NOM I NOM I NOM -20% +20% V NOM V NOM V NOM -50mV +30mV 3.1 4.0 170 240 40 77 380 400 420 480 500 520 10% 15% 5% I NOM I NOM I NOM 160 336 420 mA mA V mA V V mV mV mV mV mA nA BVDD=3.6V; Tamb=25ºC; unless otherwise specified 7.4.15.5 Register Description Charger Related Register Name IRQ_ENRD_0 Base I2C audio master Offset 0x25 Description Enable/disable EOC and battery over-temperature interrupt Read out charger status Table 140 Charger Register Name Base Default Charger I2C audio master 0x00 Offset: 0x22 Charger Register This register is reset at a DVDD-POR. Bit 7 Bit Name TMPSup_off Default 0 Access R/W 6:4 CHG_I 000 R/W 3:1 CHG_V 000 R/W 0 CHG_OFF 0 R/W Bit Description 0: enables 15uA supply for external 100k NTC resistor 1: disables supply set maximum charging current 111: 400 mA 110: 350 mA .. 001: 100 mA 000: 50 mA set maximum charger voltage 111: 4.25 V 110: 4.2 V .. 001: 3.95 V 000: 3.9 V 0: enables Charger 1: disables Charger © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 153 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.16 15V Step-Up Converter 7.4.16.1 General The integrated Step-Up DC/DC Converter is a high efficiency current-mode PWM regulator, providing an output voltage up to 15V. A constant switching-frequency results in a low noise on supply and output voltages. When using an additional transistor the output voltage can be up to 25V to drive 6 white LED in series. It has an adjustable sink current (1.25 to 38.75mA) to provide e.g. dimming function when driving white LEDs as back-light. 7.4.16.2 Parameter Table 141 15V Step-Up Converter Parameter Symbol Parameter V SW I VDD V FB V FB V PULSESKIP High Voltage Pin Quiescent Current Feedback Voltage, Transient Feedback Voltage, during Regulation Current Limit Switch Resistance Load Current Pulse-skip Threshold F IN C OUT L (Inductor) Fixed Switching Frequency Output Capacitor I LOAD > 20mA t MIN_ON MDC I LOAD < 20mA Minimum On-Time Maximum Duty Cycle I SW_MAX R SW I LOAD Notes Pin SW15 Pulse Skipping mode Pin ISINK Pin ISINK V15_ON = 1 V15_ON = 0 @ 15V output voltage Voltage at pin ISINK, pulse skips are introduces when load current becomes too low. Min Guaranteed per design Max Unit 15 V µA V V 140 0 0.65 350 0 1.2 0.5 Ceramic Use inductors with small C PARASITIC (<100pF) for high efficency Typ 0 17 8 90 88 0.83 510 0.85 5.5 1.0 750 1.54 45 1.5 mA 0.55 1 22 0.6 27 MHz µF µH 10 27 180 94 ns % 1.33 91 Ω mA V BVDD=3.6V; Tamb=25ºC; unless otherwise specified © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 154 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Figure 58 15V Step-Up Performance Characteristics Efficiency vs Output Current 100 VIN=3.6V 90 EFFICIENCY [%] 80 70 60 50 40 DCDC stepup Current controlled 0..15V 30 20 1 10 OUTPUT CURRENT [mA] 100 7.4.16.3 Register Description Table 142 DCDC15 Register Name Base Default DCDC15 I2C audio master 0x00 Offset: 0x23 Bit 7:5 4:0 Bit Name I_V15<4..0> 15V DCDC Register This register is reset at a DVDD-POR. Default 000 00000 Access n/a R/W Bit Description defines the current through the LED = 1.25mA * I_V15 00000: DCDC15 switched off 00001: 1.25mA 00010: 2.5mA .. 11110: 37.5mA 11111: 38.75mA © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 155 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.17 Supervisor 7.4.17.1 General This supervisor function can be used for automatic detection of BVDD brown out or junction over-temperature condition. 7.4.17.2 BVDD Supervision The supervision level can be set in 8 steps @ 60mV from 2.74 to 3.16V. If the level is reached an interrupt can be generated. If BVDD reaches 2.6V the AFE shuts down automatically. 7.4.17.3 Junction Temperature Supervision The temperature supervision level can also be set by 5 bits (120 to –15oC). If the temperature reaches this level, an interrupt can be generated. The over-temperature shutdown level is always 20oC higher. If the IRQ level is set to 120oC the shutdown is disabled. 7.4.17.4 Register Description Table 143 Supervisor Related Register Name IRQ_ENRD_0 IRQ_ENRD_1 Base I2C audio master I2C audio master Offset 0x25 0x26 Description Enable/disable battery brown out interrupt Enable/disable junction temperature interrupt Table 144 Supervisor Register Name Base Default Supervisor I2C audio master 0x00 Offset: 0x24 Supervisor Register This register is reset at a DVDD-POR. Bit 7:5 Bit Name BVDD_Sup<2:0> Default 000 Access R/W 4:0 JT_Sup<4:0> 00000 R/W Bit Description supervision of BVDD brown out V_BrownOut=2.74+x*60mV 000: 2.74V 001: 2.80V … 110: 3.10V 111: 3.16V junction temperature supervision: Temp_ShutDown=140-x*5°C Temp_IRQ=120-x*5°C © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 156 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.18 Interrupt Generation 7.4.18.1 General All interrupt sources can get enabled or disabled by corresponding bits in the 3 IRQ-bytes. By default no IRQ source is enabled. The IRQ output can get configured to be PUSH/PULL or OPEN_DRAIN and ACTIVE_HIGH or ACTIVE LOW with 2 bits in IRQ_ENRD_2 register (0x27). Default state is open drain and active_low. 7.4.18.2 IRQ Source Interpretation There are 3 different modules to process interrupt sources: 7.4.18.3 LEVEL The IRQ output is kept active as long as the interrupt source is present and this IRQ-Bit is enabled 7.4.18.4 EDGE The IRQ gets active with a high going edge of this source. The IRQ stays active until the corresponding IRQ-Register gets read. 7.4.18.5 STATUS CHANGE The IRQ gets active when the source-state changes. The change bit and the status can be read to notice which interrupt was the source. The IRQ stays active until the corresponding interrupt register gets read. 7.4.18.6 De-bouncer There is a de-bounc function implemented for USB and CHARGER. Since these 2 signals can be unstable for the phase of plug-in or unplug, a debounce time of 512ms/256ms/128ms can be selected by 2 bits in the IRQ_ENRD2 register (0x27h). Table 145 First Interrupt Register Name Base Default IRQ_ENRD_0 I2C audio master 0x00 Offset: 0x25 Bit 7 6 5 Bit Name CHG_tmphigh (level) CHG_endofch (edge) CHG_status First Interrupt Register Please be aware that writing to this register will enable/disable the corresponding interrupts, while with reading you get the actual interrupt status and will clear the register at the same time. It is not possible to read back the interrupt enable/disable settings. This register is reset at a DVDD-POR. Default 0 Access W x R 0 W x R x R Bit Description battery over-temperature interrupt setting 0: disable 1: enable The interrupt must not be enabled if the charger block and battery temperature supervision is disabled Battery over-temperature interrupt reading 0: battery temperature below 55°C 1: battery temperature was too high and the charger was turned off. The charger will be turned on again, when the temperature gets below 50°C Battery end of charge interrupt setting 0: disable 1: enable The interrupt must not be enabled if the charger block is disabled Battery end of charge interrupt reading 0: battery charging in progress 1: charging is complete, turn charger off To check end of charge again the charger has to be turned on. 0: no charger input source connected 1: charger input source connected, also valid if charger is connected during wakeup © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 157 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Bit 4 Name Base Default IRQ_ENRD_0 I2C audio master 0x00 Offset: 0x25 First Interrupt Register Please be aware that writing to this register will enable/disable the corresponding interrupts, while with reading you get the actual interrupt status and will clear the register at the same time. It is not possible to read back the interrupt enable/disable settings. This register is reset at a DVDD-POR. Bit Name CHG_changed (status change) 0 Access W x R Default 3 USB_status x R 2 USB_changed (status change) 0 W x R 0 W x R 0 W x R 1 0 RVDD_waslow (level) BVDD_islow Bit Description Charger input status change interrupt setting 0: disable 1: enable enables an interrupt on a low to high or high to low change of CHG_IN pin. The thresholds are set in Charger input status change interrupt reading 0: charger input status not changed 1: charger input status changed, check CHG_status 0: no USB input connected 1: USB input connected, also valid if USB is connected during wakeup USB input status change interrupt setting 0: disable 1: enables an interrupt on a low to high or high to low change of VBUS pin. The threshold can be set in the USB_UTIL register (0x17) USB input status change interrupt reading 0: USB input status not changed 1: USB input status changed, check USB_status Real time clock supply interrupt setting 0: disable 1: enable Real time clock supply interrupt reading 0: RTC supply o.k. 1: RTC supply was low, RTC not longer valid The interrupt gets set during power-up even if the interrupt is not enabled. For a valid reading, the interrupt has to be enabled first. Supervisor BVDD interrupt setting 0: disable 1: enable Supervisor BVDD interrupt setting 0: BVDD is above brown out level 1:BVDD has reached brown out level The threshold can be set in the SUPERVISOR register (0x24) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 158 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 146 Second Interrupt Register Bit 7 6 5 Name Base Default IRQ_ENRD_1 I2C audio master 0x00 Offset: 0x26 Second Interrupt Register Please be aware that writing to this register will enable/disable the corresponding interrupts, while with reading you get the actual interrupt status and will clear the register at the same time. It is not possible to read back the interrupt enable/disable settings. This register is reset at a DVDD-POR. Bit Name JTEMP_high (level) 0 Access W x R 0 W x R 0 W x R LSP_overcurr (level) HPH_overcurr (level) Default 4 I2S_status x R 3 I2S_changed (status change) 0 W x R 0 W x R 2 MIC2_connect (level) Bit Description Supervisor junction over-temperature interrupt setting 0: disable 1: enable Supervisor junction over-temperature interrupt reading 0: chip temperature below threshold 1: chip temperature has reached the threshold The threshold can be set in the SUPERVISOR register (0x24) Speaker over-current interrupt setting 0: disable 1: enable The interrupt must not be enabled if the speaker block is disabled Speaker over-current interrupt reading 0: no over-current detected 1: speaker over-current detected, speaker amplifier was shut down. The shut-down time can be set in LSP_OUT_R register (0x04) Headphone over-current interrupt setting 0: disable 1: enable The interrupt must not be enabled if the headphone block is disabled Headphone over-current interrupt reading 0: no over-current detected 1: headphone over-current detected, headphone amplifier was shut down. The shut-down time can be set in HPH_OUT_R register (0x02) 0: no LRCK on I2S interface detected 1: LRCK on I2S interface present I2S input status change interrupt setting 0: disable 1: enable I2S input status change interrupt reading 0: I2S input status not changed 1: I2S input status changed, check I2S_status Microphone 2 connect detection interrupt setting 0: disable 1: enable Microphone 2 connect detection interrupt reading 0: no microphone connected to MIC2 input 1: microphone connected at MIC2 input. IRQ will be released after enabling the microphone stage. Detecting a microphone during operation has to be done by measuring the supply current. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 159 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 1 0 MIC1_connect (level) HPH_connect (level) 0 W x R 0 W x R Microphone 1 connect detection interrupt setting 0: disable 1: enable Microphone 1 connect detection interrupt reading 0: no microphone connected to MIC1 input 1: microphone connected at MIC1 input. IRQ will be released after enabling the microphone stage. Detecting a microphone during operation has to be done by measuring the supply current. Headphone connect detection interrupt setting 0: disable 1: enable Headphone connect detection interrupt reading 0: no headphone connected 1: headphone connected IRQ will be released after enabling the headphone stage. Detecting a headphone during operation is not possible. Table 147 Third Interrupt Register Name Base Default IRQ_ENRD_2 I2C audio master 0x00 Offset: 0x27 Third Interrupt Register Please be aware that writing to this register will enable/disable the corresponding interrupts, while with reading you get the actual interrupt status and will clear the register at the same time. It is not possible to read back the interrupt enable/disable settings. This register is reset at a DVDD-POR. Bit 7:6 Bit Name T_deb<1:0> Default 00 Access R/W 5 IRQ_Acthigh 0 R/W 4 IRQ_PushPull 0 R/W 3 Remote_Det2 (edge) 0 W x R 0 W x R 0 W 2 1 Remote_Det1 (edge) RTC_update (edge) Bit Description Sets the USB and Charger connect de-bounce time: 00: 512ms 01: 256ms 10: 128ms 11: not defined Sets the active output state of the INTRQ line: 0: IRQ is active low 1: IRQ is active high Sets the INTRQ output buffer type: 0: IRQ output is open drain 1: IRQ output is push pull Microphone 2 remote key press detection interrupt setting 0: disable 1: enable Microphone 2 remote key press detection interrupt reading 0: no key press detected 1: Microphone 2 supply current got increased, remote key press detected -> measure MSUP2 supply current Microphone 1 remote key press detection interrupt setting 0: disable 1: enable Microphone 1 remote key press detection interrupt reading 0: no key press detected 1: Microphone 1 supply current got increased, remote key press detected -> measure MSUP1 supply current RTC timer interrupt setting 0: disable 1: enable © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 160 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Name Base Default IRQ_ENRD_2 I2C audio master 0x00 Offset: 0x27 Bit 0 Third Interrupt Register Please be aware that writing to this register will enable/disable the corresponding interrupts, while with reading you get the actual interrupt status and will clear the register at the same time. It is not possible to read back the interrupt enable/disable settings. This register is reset at a DVDD-POR. Bit Name ADC_EndCon (edge) x Default Access R 0 W x R Bit Description RTC timer interrupt reading 0: not RTC interrupt occurred 1: RTC timer interrupt occurred.Selecting minute or second interrupt can be done via RTCT register (0x29) ADC end of conversion interrupt setting 0: disable 1: enable ADC end of conversion interrupt reading 0: ADC conversion not finished 1: ADC conversion finished. Read out ADC_0 and ADC_1 register to get the result (0x2E & 0x2F) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 161 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.19 Real Time Clock 7.4.19.1 General The real time clock block is an independent block, which is still working even when the chip is shut down. The only condition for this operation is that BVDD has a voltage of above 1.0V. The block uses a standard 32kHz crystal that is connected to a low power oscillator. An internal 32bit second register stores the current time. The RTC block has special functions for trimming the time base and generating interrupts every second or minute. 7.4.19.2 RTC supply The internal RTC is supplied via the BVDD pin. The block has an internal LDO to generate the RTC supply voltage on RVDD pin. This voltage can be programmed via the RTCV register (0x28h). If the internal RTC is not used, RVDD can be used to supply an external RTC block. If the supply voltage on BVDD pin rises, the whole chip gets powered up. See also power-up conditions in chapter 7.4.1.2. 7.4.19.3 Register Description Table 148 RTC Related Register Name IRQ_ENRD_0 IRQ_ENRD_2 Base I2C audio master I2C audio master Offset 0x25 0x27 Description Interrupt settings for RVDD under-voltage detection Interrupt settings for getting a second or minute interrupt Table 149 RTCV Register Name Base Default RTCV I2C audio master 0x23 Offset: 0x28 RTC Voltage Register This register is reset at a RVDD-POR. (DVDD_POR for C21O20) Bit 7:4 Bit Name VRTC<3..0> Default 0010 Access R/W 3:2 1 RTC_ON 00 1 n/a R/W 0 OSC_ON 1 R/W Bit Description Sets the RTC supply voltage, 16 steps @ 0.1V, default is 1.2V 0000: 1V 0001: 1.1V 0010: 1.2V … 1110: 2.4V 1111: 2.5V do not change RTC clock control: 0: Disable clock for RTC 1: Enables clock for RTC RTC oscillator control: 0: Disables RTC oscillator 1: Enables RTC oscillator © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 162 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 150 RTCV Register Name Base Default RTCT I2C audio master 0x40 Offset: 0x29 RTC Timing Register This register is reset at a RVDD-POR. (DVDD_POR for C21O20) Bit 7 Bit Name IRQ_MIN Default 0 Access R/W 6:0 TRTC<6:0> 1000000 R/W Bit Description 0: generates an interrupt every second 1: generates an interrupt every minute Trimming register for RTC, 128 steps @ 7.6ppm 000000: 1 (7.6ppm) 000001: 2 (15.2ppm) … 100000: 64 (488ppm) … 111110: 126 (960.8ppm) 111111: 127 (968.4ppm) Table 151 RTC_0 to RTC_3 Register Name Base Default RTC_0 to RTC_3 I2C audio master 0x00 00 00 00 Offset: 0x2A to 0x2D Adr. 0x2A 0x2B 0x2C 0x2D Byte Name RTC_0 RTC_1 RTC_2 RTC_3 Unique ID Register This register is reset at a RVDD-POR. Default 0x00 0x00 0x00 0x00 Access R/W R/W R/W R/W Bit Description RTC<7:0>; RTC seconds bits 0 to 7 RTC<15:8>; RTC seconds bits 8 to 15 RTC<23:9>; RTC seconds bits 9 to 23 RTC<31:24>; RTC seconds bits 24 to 31 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 163 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.20 10-Bit ADC 7.4.20.1 General This general purpose ADC can be used for measuring several voltages and currents to perform functions like battery monitor, temperature supervision, button press detection, etc.. . Please note that C21O20 is measuring BVDD instead of CHG_OUT 7.4.20.2 Input Sources Table 152 ADC10 Input Sources Nr. 0 1 Source CHG_OUT RTCSUP Range 5.120V 5.120V LSB 5mV 5mV 2 3 4 5 6 VBUS CHG_IN CVDD BatTemp MicSup1 5.120V 5.120V 2.560V 2.560V 2.560V 5mV 5mV 2.5mV 2.5mV 2.5mV 7 MicSup2 2.560V 2.5mV 8 9 10 11 12 13..15 VBE1 VBE2 I_MicSup1 I_MicSup2 VBAT Reserved 1.024 1.024 1.024mA typ. 1.024mA typ. 2.560V 1.024V 1mV 1mV 1.0uA 1.0uA 2.5mV 1mV Description check battery voltage of 4V LiIo accumulator check RTC backup battery voltage (connected to BVDD inside the package) check USB host voltage check charger input voltage check charge pump output voltage check battery charging temperature check voltage on MicSup1 for remote control or external voltage measurement check voltage on MicSup2 for remote control or external voltage measurement measuring junction temperature measuring junction temperature check current of MicSup1 for remote control detection check current of MicSup2 for remote control detection check single cell battery voltage for testing purpose only CHG_OUT, RTCSUP, VBUS, CHG_IN These sources are fed into an 1/5 voltage divider (180kΩ typ.) and further amplified by 2.5. CVDD, BatTemp, MicSup1, MicSup2 These sources are fed directly to the ADC input multiplexer. VBE1, VBE2 These inputs are first amplified by 2.5 and than fed to the ADC input multiplexer. I_MicSup1, I_MicSup2 The measurement of the microphone supply LDOs is not very accurate, as the current-voltage conversion is only done by a single resistor which shows wide process and temperature variations. These measurements should be only used for remote function detection. VBAT This source is divided by 2.5 with a voltage divider (180kΩ typ.) and than amplified by 2.5. This has to be done, as VBAT can represent voltages up to 3.6V. Please note, that the maximum measurement rage will be still 2.560V 7.4.20.3 Reference AVDD=2.9V is used as reference to the ADC. AVDD is trimmed to +/-20mV with over all precision of +/-29mV. So the absolute accuracy is +/-1%. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 164 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.20.4 Parameter Table 153 ADC10 Parameter Symbol R DIV ADC FS Ratio1 Ratio2 Gain T CON I_MIC FS Parameter Input Divider Resistance Notes CHG_OUT, RTCSUP, VBUS, CHG_IN, VBAT ADC Full Scale Range Divition Factor 1 CHG_OUT, RTCSUP, VBUS, CHG_IN Divition Factor 2 VBAT ADC Gain Stage Conversion Time I_MicSup1/2 Full Scale Range Min 138k Typ 180k Max 234k Unit 2.534 0.198 0.396 2.475 0.7 2.56 0.2 0.4 2.5 34 1.0 2.586 0.202 0.404 2.525 50 1.4 V 1 1 V µs mA Ω BVDD=3.6V; Tamb=25ºC; unless otherwise specified 7.4.20.5 Register Description Table 154 ADC10 Related Register Name IRQ_ENRD_2 Base I2C audio master Offset 0x27 Description Interrupt settings for end of conversion interrupt Table 155 ADC_0 Register Name Base Default ADC_0 I2C audio master 0000 00xx Offset: 0x2E First 10-bit ADC Register Writing to this register will start the measurement of the selected source. This register is reset at a DVDD-POR, exception are bit 8 and 9. Bit 7:4 Bit Name ADC_Source Default 00000000 Access R/W 3:2 1:0 ADC<9:8> 00 xx n/a R/W Bit Description Selects ADC input source 0000: CHG_OUT 0001: RTCSUP 0010: VBUS 0011: CHG_IN 0100: CVDD 0101: BatTemp 0110: MicSup1 0111: MicSup2 1000: VBE_1uA 1001: VBE_2uA 1010: I_MicSup1 1011: I_MicSup2 1100: VBAT 1101: reserved 1110: reserved 1101: reserved do not change ADC result bit 9 to 8 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 165 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Table 156 ADC_1 Register Name Base Default ADC_1 I2C audio master xxxx xxxx Offset: 0x2F Bit 7:0 Bit Name ADC<7:0> Second 10-bit ADC Register This register is not reset. Default xxxx xxxx Access R/W Bit Description ADC result bit 7 to 0 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 166 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.21 128 bit OTP ROM 7.4.21.1 General This fuse array is used to store a unique identification number, which can be used for DRM issues. The number is generated and programmed during the production process. 7.4.21.2 Register Description Table 157 UID_0 to UID_15 Register Name Base Default UID_0 to UID_15 I2C audio master n/a Offset: 0x30 to 0x3F Adr. 0x30 0x31 0x32 0x33 0x34 0x35 0x36 0x37 0x38 0x39 0x3A 0x3B 0x3C 0x3D 0x3E 0x3F Byte Name UID_0 UID_1 UID_2 UID_3 UID_4 UID_5 UID_6 UID_7 UID_8 UID_9 UID_10 UID_11 UID_12 UID_13 UID_14 UID_15 Unique ID Register This register is read only and is not reset. Default 0x00 0x00 0x00 0x00 0x00 0x00 0x00 0x00 n/a n/a n/a n/a n/a n/a n/a n/a Access R R R R R R R R R R R R R R R R Bit Description Unique Unique Unique Unique Unique Unique Unique Unique Unique Unique Unique Unique Unique Unique Unique Unique ID ID ID ID ID ID ID ID ID ID ID ID ID ID ID ID byte byte byte byte byte byte byte byte byte byte byte byte byte byte byte byte 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 167 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.22 2-Wire-Serial Control Interface 7.4.22.1 General There is an I2C slave block implemented to have access to 64 byte of setting information. The I2C address is: Adr_Group8 - audio processors • • 8Ch_write 8Dh_read Figure 59 I2C timing 7.4.22.2 Parameter Table 158 I2C Operating Conditions Symbol V IL V IH HYST V OL T sp TH TL T SU T HD TS T PD Parameter Input low voltage Input high voltage Hysteretic Output low voltage Spike insensitivity Clock high time Clock low time Data setup time Notes CSCL, CSDA (max 30%DVDD) CSCL, CSDA (min 70%DVDD) CSCL, CSDA CSDA @3mA CSDA has to change T SU before rising edge of CSCL Data hold time No hold time needed for CSDA relative to rising edge of CSCL Clock start-condition hold time CSCL HIGH hold time relative to CSDA edge for start/stop/rep_start Output delay CSDA propagation delay relative to low going edge of CSCL Min 0 2.03 200 50 500 500 100 Typ 450 100 Max Unit 0.87 5.5 800 0.4 V V mV V ns ns ns ns 0 ns 200 ns 24 50 80 ns DVDD =2.9V, Tamb=25ºC; unless otherwise specified © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 168 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 7.4.22.3 Register Description Registers Overview (00h to 3Fh) Table 159 I2C Register Overview Addr Name D<7> D<6> 00h LINE_OUT_R reserved 01h 0 0 LINE_OUT_L LO_SES_DM<1:0> 02h 0 0 HPH_OUT_R HP_OVC_TO<1:0> 03h 04h 05h HPH_OUT_L LSP_OUT_R LSP_OUT_L 06h MIC1_R 07h MIC1_L 08h MIC2_R 09h MIC2_L 0Ah Line_IN1_R 0Bh Line_IN1_L 0Ch Line_IN2_R 0Dh Line_IN2_L 0Eh DAC_R 0 0 HP_Mute_ HP_on on 0 0 SP_OVC_TO<1:0> 0 0 SP_Mute_ SP_on on 0 Mic1_AGC _off 0 Mic1_Sup _off 0 Mic2_AGC _off 0 Mic2_Sup _off 0 - D<5> D<4> D<3> LOR_Vol<4:0> Gain from Mixer_Out 0 0 0 LOL_Vol<4:0> Gain from Mixer_Out 0 0 0 HPR_Vol<4:0> Gain from Mixer_Out 0 0 0 HPdet_on HPL_Vol<4:0> Gain from Mixer_Out 0 0 0 SPR_Vol<4:0> Gain from Mixer_Out 0 0 0 SPL_Vol<4:0> Gain from Mixer_Out D<2> D<1> D<0> - to Line_Out= (-40.5dB … +6dB) 0 0 0 to Line_Out= (-40.5dB … +6dB) 0 0 0 to HPH_Out= (-45.43dB … +1.07dB) 0 0 0 to HPH_Out= (-45.43dB … +1.07dB) 0 0 0 to LSP_Out= (-40.5dB … +6.0dB) 0 0 0 to LSP_Out= (-40.5dB … +6.0dB) 0 0 Mic1_Gain<1:0> 0 0 0 0 0 Mic1R_Vol<4:0> Gain from MicAmp_Out to Mixer_In= (-40.5dB … +6.0dB) 0 0 0 0 0 0 0 Mic1_Mute Mic1L_Vol<4:0> _off Gain from MicAmp_Out to Mixer_In= (-40.5dB … +6.0dB) 0 0 0 0 0 0 0 Mic2_Gain<1:0> Mic2R_Vol<4:0> Gain from MicAmp_Out to Mixer_In= (-40.5dB … +6.0dB) 0 0 0 0 0 0 0 Mic2_Mute Mic2L_Vol<4:0> _off Gain from MicAmp_Out to Mixer_In= (-40.5dB … +6.0dB) 0 0 0 0 0 0 0 LI1R_Mut LI1R_Vol<4:0> e Gain from LineIn_Pin to Mixer_In=-34.5dB+LI1R_VOL*1.5dB _off (-34.5dB … +12dB) 0 0 0 0 0 0 0 0 LI1_Mode<1:0> LI1L_Mut LI1L_Vol<4:0> e Gain from LineIn_Pin to Mixer_In= (-34.5dB … +12dB) _off 0 0 0 0 0 0 0 0 LI2R_Mut LI2R_Vol<4:0> e_off Gain from LineIn_Pin to Mixer_In= (-34.5dB … +12dB) 0 0 0 0 0 0 0 0 LI2_Mode<1:0> LI2L_Mut LI2L_Vol<4:0> e_off Gain from LineIn_Pin to Mixer_In= (-34.5dB … +12dB) 0 0 0 0 0 0 0 0 DAR_Vol<4:0> Gain from DAC_Out to Mixer_In= (-40.5dB … +6dB) 0 0 0 0 0 0 0 0 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 169 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Addr 0Fh 10h 11h 14h 15h 16h 17h 1Dh 20h 21h 22h 23h 24h 25h 26h 27h 28h 29h 2Ah 2Bh 2Ch 2Dh 2Eh Name D<7> D<6> D<5> D<4> D<3> D<2> D<1> D<0> DAL_Vol<4:0> Gain from DAC_Out to Mixer_In= (-40.5dB … +6dB) 0 0 0 0 0 ADC_R ADR_Vol<4:0> Gain from ADCMux_Out to ADC_In= (-34.5dB … +12dB) 0 0 0 0 0 0 0 0 ADC_L AD_FS2 ADC_Mute ADL_Vol<4:0> _off Gain from ADCMux_Out to ADC_In= (-34.5dB … +12dB) 0 0 0 0 0 0 0 0 AudioSet1 ADC_on SUM_on DAC_on LOUT_on LIN2_on LIN1_on MIC2_on MIC1_on 0 0 0 0 0 0 0 0 AudioSet2 BIAS_off DITH_off AGC_off IBR_DAC<1:0> LSP_LP IBR_LSP<1:0> 0 0 0 0 0 0 0 0 AudioSet3 ZCU_OFF IBR_HPH HPCM_off 0 0 0 0 0 0 0 0 USB_UTIL LDO6_on COMP_TH<1:0> SKIP_ENAB CP_5V_on 0 0 0 0 0 0 0 0 CLOCK_OUT CLK_OUT_mode<1:0> CLKOUT_drive<1:0> OSC_pd 0 0 0 0 0 0 0 0 SYSTEM Design_Version<3:0> PVDDp IOVDDp EnWDogPw PwrUPHld dn 0 0 1 0 0 0 0 1 CVDD/DCDC3 CP_SW CP_on LREG_C DCDC3p<1:0> LREG_off CVDDp<1:0> P_not 0 0 0 0 0 0 0 0 CHARGER TmpSup_ CHGI<2:0> CHGV<2:0> CHG_off off 0 0 0 0 0 0 0 0 DCDC15 I_V15<4:0> 0 0 0 0 0 0 0 0 SUPERVISOR BVDD_Sup<2:0> JT_Sup<4:0> 0 0 0 0 0 0 0 0 IRQ_ENRD0 CHG CHG CHG CHG USB USB RVDD BVDD tmphigh endofch status changed status changed was low Is low 0 0 0 0 0 0 0 0 IRQ_ENRD1 JTEMP LSP HPH I2S I2S Mic2 Mic1 HeadPh high overcurr overcurr status changed connect connect Connect 0 0 0 0 0 0 0 0 IRQ_ENRD2 T_deb<1:0> IRQ_ActH IRQ_PushP Remote_Det Remote_D RTC_Updat ADC_EndCo igh ull 2 et1 e n 0 0 0 0 0 0 0 0 RTCV VRTC<3:0> RTC_ON OSC_ON 0 0 1 0 0 0 1 1 RTCT IRQ_MIN TRTC<6:0> 0 1 0 0 0 0 0 0 RTC_0 RTC<7:0> 0 0 0 0 0 0 0 0 RTC_1 RTC<15:8> 0 0 0 0 0 0 0 0 RTC_2 RTC<23:16> 0 0 0 0 0 0 0 0 RTC_3 RTC<31:24> 0 0 0 0 0 0 0 0 ADC_0 ADC_Source<3:0> ADC<9:8> 0 0 0 0 0 0 X X DAC_L DAC_Mute _off 0 0 0 ADCmux<1:0> - © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 170 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Addr Name 2Fh ADC_1 30-3F UID_0 .. 15 D<7> D<6> ADC<7:0> X X ID<7:0> … ID<127:120> D<5> X D<4> X D<3> X D<2> X D<1> X © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 D<0> X 171 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 8 Pinout and Packaging 8.1 Package Variants CTBGA (Thin ChipArray BGA) package technology is used for multi-chip-module (MCM) packaging. The following package variants are available for the product: Table 160 Package Options Product Code Package Balls Ball Matrix Pitch [mm] Height [mm] Size [mm] Application CTBGA CTBGA 224 144 15x15, 7 Row 12x12, full 0.8 0.8 1.2 1.2 13x13 10x10 with external SDRAM interface w/o external SDRAM interface AS3525-A AS3525-B 8.2 CTBGA224 Package Drawings 8.2.1 Marking Figure 60 CTBGA224 Package Marking AS3525A C22O22 AYWWZZZ Package Code AYYWWZZZ A Y WW ZZZ A … for PB free Year working week assembly/packaging Free choice Figure 61 CTBGA224 Package Drawing © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 172 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 8.2.2 CTBGA224 Package Ball-out Figure 62 AS3525A Package Ball--out 1 2 3 4 A jtag_tms xpc_7 xpc_3 xpa_2 B jtag_tdi jtag_tck xpc_5 xpa_0 C i2si_sdata_in jtag_trst_n xpc_6 xpc_1 xpa_6 mpmc_addr_7 mpmc_addr_15 D i2si_lrck_out tmsel jtag_tdo xpc_4 xpa_4 mpmc_addr_5 mpmc_addr_13 mpmc_dqm_0 mpmc_stcs_n_0 mpmc_oe_n E clk_ext clk_sel i2si_sclk_out i2si_mclk xpc_0 mpmc_addr_8 mpmc_addr_14 F id_dig usb_vdda33t VBUS xpc_2 xpa_7 mpmc_addr_6 mpmc_addr_16 mpmc_cke_0 G usb_dp usb_vssa33t dbop_d12 xpa_1 mpmc_addr_0 mpmc_addr_18 H usb_dm usb_vssa33t dbop_d13 xpa_3 mpmc_addr_10 mpmc_addr_20 mpmc_data_8 xpa_5 mpmc_addr_12 mpmc_cke_1 J usb_vssa33c usb_rkelvin_rext usb_vdda33c 5 6 7 8 12 13 14 15 mpmc_addr_3 mpmc_addr_9 mpmc_addr_17 mpmc_cas_n mpmc_bls_n_0 mpmc_data_5 mpmc_data_13 ide_ha_0 naf_d_1 dbop_d14 vdd_peri mpmc_addr_1 mpmc_addr_11 mpmc_addr_19 mpmc_clk_1 mpmc_ras_n 9 10 11 vss_mem vdd_mem mpmc_data_7 mpmc_data_15 naf_d_7 naf_d_4 naf_d_2 vss_peri vss_mem vdd_mem mpmc_data_9 ssp_fssout naf_d_5 naf_d_0 naf_d_8 dbop_d15 ssp_rxd ide_ha_2 naf_d_3 naf_d_14 naf_d_11 naf_d_9 naf_d_13 naf_d_15 naf_ce0_n mpmc_clk_0 mpmc_dycs_n_1 mpmc_data_1 mpmc_data_11 mpmc_we_n mpmc_data_10 mpmc_data_12 ssp_clkout mpmc_data_6 mpmc_data_14 mpmc_data_3 naf_d_10 naf_d_12 naf_ale naf_cle naf_bsy_n ide_reset_n naf_d_6 naf_wp_n naf_ce3_n naf_we_n xpd_3 ide_ha_1 naf_ce1_n naf_re_n xpd_0 xpd_4 xpd_7 ssp_txd naf_ce2_n xpd_1 xpd_2 xpd_5 xpd_6 xpb_3 xpb_2 xpb_5 xpb_7 SW_15V SW_3V xpb_0 xpb_1 xpb_6 CN_5V CP_5V VSS_3V K vdd_core nc DVDD nc L vss_core nc PwrUP mpmc_addr_2 mpmc_fbclkin M CLK_OUT XRES CSDA CSCL MCLK SDI SDO VREF HPCM BATTEMP ISINK VSS_15V VBAT_1V QLDO2 VSS_1V N INTRQ P_PVDD MSUP2 LOUTR LRCK SCLK LOUTL AVDD HPGND HPR BGND BVSS2 HPL CHG_IN CN_1V P DVSS LIN2R LIN1R MIC2_N MIC1_N MSUP1 BVSS AGND BVDD BVDD BVDD IOVDD RVDD CHG_OUT CP_1V R XIN_24M XOUT_24M LIN2L LIN1L MIC2_P MIC1_P AVSS BVSS LSPR LSPL UVDD PVDD XIN_32k XOUT_32k CVDD Note: mpmc_addr_4 mpmc_dycs_n_0 mpmc_bls_n_1 mpmc_data_4 xpb_4 mpmc_dqm_1 mpmc_stcs_n_1 mpmc_data_0 mpmc_data_2 PINs K2, L2 and K4 are reserved for production test purposes and must be left not connected for normal operation mode. 8.2.3 CTBGA224 Ball List Table 161 CTBGA224 Ball List Ball Nr. BGA224 Ball Name PAD Type E1 XRES resetext_n CLK_OUT clk_int clk_ext DO D IN ST DO D IN ST D IN ST PD E2 clk_sel D IN ST PD D2 tmsel D IN ST PD F1 id_dig D IN ST (PU) M2 M1 I/O Ball Description O I O I I XRES is generated by the PMU subsystem and connected to reset input (active low) on the BGA CLK_OUT is output of 20-24MHz crystal oscillator clock and connected to clk_int on the BGA external clock input (10-26MHz) I clock select 0 (low): clock from internal oscillator is used 1 (high): clock from pad clk_ext is used test mode select For testing purpose only, has to be set to “0”. USB mini receptacle identifier Has to be connected to USB jack ID pin. I I © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 173 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA224 Ball Name PAD Type I/O Ball Description Port A B4 xpa[0] D IO ST PD LSR IO GPIO IO, Port A G4 xpa[1] D IO ST PD LSR IO GPIO IO, Port A A4 xpa[2] D IO ST PD LSR IO GPIO IO, Port A H4 xpa[3] D IO ST PD LSR IO GPIO IO, Port A D5 xpa[4] D IO ST PD LSR IO GPIO IO, Port A J4 xpa[5] D IO ST PD LSR IO GPIO IO, Port A C5 xpa[6] D IO ST PD LSR IO GPIO IO, Port A F5 xpa[7] D IO ST PD LSR IO GPIO IO, Port A IO GPIO IO, Port B I Port B / DISPLAY / UART xpb[0] L10 L11 K11 K10 K9 K12 dbop_c0 O static memory chip memory width setting for boot loader 0: 8 bit data bus 1: 16 bit data bus The value is latched at reset. DISPLAY control output xpb[1] IO GPIO IO, Port B I mpmc_stcs1mw[0 D IO ST PD LSR ]* dbop_c1 O static memory chip select polarity setting for boot loader 0: active LOW chip select 1: active high chip select The value is latched at reset. DISPLAY control output xpb[2] IO GPIO IO, Port B I mpmc_stcs1pol* D IO ST PD LSR dbop_c2 O static memory byte lane polarity setting for boot loader 0: HIGH for reads, LOW for writes, used for we_n access 1: LOW for reads, LOW for writes, used for upper and lower byte access The value is latched at reset. DISPLAY control output xpb[3] IO GPIO IO, Port B I mpmc_stcs1pb* D IO ST PD LSR dbop_c3 O test mode configuration (for testing purpose only !!!) The value is latched at reset. DISPLAY control output xpb[4] IO GPIO IO, Port B IO DISPLAY data input/output (high byte) IO GPIO IO, Port B IO DISPLAY data input/output (high byte) IO GPIO IO, Port B mpmc_rel1config* D IO ST PD LSR dbop_d[8] xpb[5] dbop_d[9] D IO ST PD LSR D IO ST PD LSR xpb[6] L12 K13 I UART receive line dbop_d[10] IO DISPLAY data input/output (high byte) xpb[7] IO GPIO IO, Port B uart_rxd uart_txd D IO ST PU LSR D IO ST PU LSR dbop_d[11] O UART transmit line IO DISPLAY data input/output (high byte) IO GPIO IO, Port C I IO BOOT LOADER source select input 1: internal ROM 0: external ROM/Flash DISPLAY data input/output (low byte) IO GPIO IO, Port C Port C / DISPLAY / 2-WIRE SERIAL xpc[0] E5 IntBootSel* D IO ST PD LSR dbop_d[0] C4 xpc[1] D IO ST PD LSR © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 174 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA224 F4 A3 Ball Name PAD Type B3 I BOOT LOADER type select input dbop_d[1] IO DISPLAY data input/output (low byte) xpc[2] IO GPIO IO, Port C boot_sel[1] I BOOT LOADER type select input dbop_d[2] IO DISPLAY data input/output (low byte) xpc[3] IO GPIO IO, Port C I BOOT LOADER type select input IO DISPLAY data input/output (low byte) boot_sel[2] D IO ST PD LSR D IO ST PD LSR xpc[4] dbop_d[4] xpc[5] dbop_d[5] D IO ST PD LSR D IO ST PD LSR xpc[6] C3 A2 Ball Description boot_sel[0] dbop_d[3] D4 I/O IO GPIO IO, Port C IO DISPLAY data input/output (low byte) IO GPIO IO, Port C IO DISPLAY data input/output (low byte) IO GPIO IO, Port C IO 2-WIRE SERIAL master/slave clock line dbop_d[6] IO DISPLAY data input/output (low byte) xpc[7] IO GPIO IO, Port C cmd_ms_sck cmd_ms_sda D IO ST PU LSR D IO ST PU LSR dbop_d[7] IO 2-WIRE SERIAL master/slave data line IO DISPLAY data input/output (low byte) Port D / SD Card / Memory Stick xpd[0] H13 J12 J13 IO GPIO IO, Port D IO MMC/SD data line ms_sdio[0] IO MEMORY STICK data line xpd[1] IO GPIO IO, Port D mci_dat[1] IO MMC/SD data line ms_sdio[1] IO MEMORY STICK data line xpd[2] IO GPIO IO, Port D IO MMC/SD data line IO MEMORY STICK data line mci_dat[0] mci_dat[2] D IO ST LSR D IO ST LSR D IO ST LSR ms_sdio[2] xpd[3] G15 H14 IO GPIO IO, Port D IO MMC/SD data line ms_sdio[3] IO MEMORY STICK data line xpd[4] IO GPIO IO, Port D O MMC/SD command line O MEMORY STICK clock line IO GPIO IO, Port D mci_dat[3] mci_cmd D IO ST LSR D IO ST LSR ms_sclk xpd[5] J14 mci_clk D IO ST LSR ms_bs J15 H15 O MMC/SD clock line O MEMORY STICK bus state xpd[6] IO GPIO IO, Port D mci_fbclk I MMC/SD feedback clock D IO ST LSR ms_fbclk I MEMORY STICK feedback clock xpd[7] IO GPIO IO, Port D O MMC/SD resistor open drain control O 2-wire serial audio master clock line used for controlling the audio/PMU sub system 2-wire serial audio master data line used for controlling the audio/PMU sub system mci_rod D IO ST LSR 2-wire serial Audio Master M4 CSCL D IO ST PU LSR M3 CSDA D IO ST PU LSR O Serial Synchronous Port © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 175 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA224 C11 H9 Ball Name ssp_fssout ssp_fssin ssp_clkout ssp_clkin D11 ssp_rxd J10 ssp_txd PAD Type I/O Ball Description O SSP master, frame or slave select I SSP slave, frame select O SSP master, clock line I SSP slave, clock line D IO ST PU LSR I SSP receive data input D IO ST PU LSR O SSP transmit data output IO NAND FLASH data line (low byte) IO IDE data line (low byte) D IO ST PU LSR D IO ST PU LSR NandFlash / IDE C13 A13 B14 D13 B13 C12 G11 B12 C14 E12 F11 D15 F12 E13 D14 E14 naf_d[0] ide_hd[0] naf_d[1] ide_hd[1] naf_d[2] ide_hd[2] naf_d[3] ide_hd[3] naf_d[4] ide_hd[4] naf_d[5] ide_hd[5] naf_d[6] ide_hd[6] naf_d[7] ide_hd[7] naf_d[8] ide_hd[8] naf_d[9] ide_hd[9] naf_d[10] ide_hd[10] naf_d[11] ide_hd[11] naf_d[12] ide_hd[12] naf_d[13] ide_hd[13] naf_d[14] ide_hd[14] naf_d[15] ide_hd[15] D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR naf_cle F14 ide_dmarq D IO ST LSR naf_ale F13 ide_iordy G12 ide_intrq IO NAND FLASH data line (low byte) IO IDE data line (low byte) IO NAND FLASH data line (low byte) IO IDE data line (low byte) IO NAND FLASH data line (low byte) IO IDE data line (low byte) IO NAND FLASH data line (low byte) IO IDE data line (low byte) IO NAND FLASH data line (low byte) IO IDE data line (low byte) IO NAND FLASH data line (low byte) IO IDE data line (low byte) IO NAND FLASH data line (low byte) IO IDE data line (low byte) IO NAND FLASH data line (high byte) IO IDE data line (high byte) IO NAND FLASH data line (high byte) IO IDE data line (high byte) IO NAND FLASH data line (high byte) IO IDE data line (high byte) IO NAND FLASH data line (high byte) IO IDE data line (high byte) IO NAND FLASH data line (high byte) IO IDE data line (high byte) IO NAND FLASH data line (high byte) IO IDE data line (high byte) IO NAND FLASH data line (high byte) IO IDE data line (high byte) IO NAND FLASH data line (high byte) IO IDE data line (high byte) O NAND FLASH command latch enable I IDE DMA request used for DMA data transfers between host and device NAND FLASH address latch enable O D IO ST LSR naf_wp_n I O D IO ST PD LSR I IDE IO ready signal used by device to extend host data transfer cycles NAND FLASH write protect not IDE interrupt request used by device to interrupt the host controller © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 176 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA224 Ball Name PAD Type naf_ce0_n E15 ide_cs0_n D IO ST LSR naf_ce1_n H11 J11 G13 ide_cs1_n naf_ce2_n ide_hiown naf_ce3_n ide_hiorn D IO ST LSR D IO ST LSR D IO ST LSR H12 F15 ide_dackn naf_re_n ide_npcblid naf_bsy_n ide_nscblid D IO ST LSR D IO ST LSR D IO ST LSR Ball Description O NAND FLASH chip enable O IDE chip select 0 used by the host to select command block registers in the device NAND FLASH chip enable O naf_we_n G14 I/O O O IDE chip select 1 used by the host to select control block registers in the device NAND FLASH chip enable O IDE host IO write strobe O NAND FLASH chip enable O IDE host IO read strobe O NAND FLASH write enable not O O IDE DMA acknowledge used by the host to initiate DMA data transfers NAND FLASH read enable not I IDE primary channel cable ID detect I NAND FLASH ready / busy not I IDE secondary channel cable ID select A12 ide_ha[0] D OUT LSR O IDE host address H10 ide_ha[1] D OUT LSR O IDE host address D12 ide_ha[2] D OUT LSR O IDE host address G10 ide_reset_n D OUT LSR O IDE reset not, used by the host to reset the device I2S Output M6 i2so_sdata SDI D OUT LSR DI O I N6 i2so_sclk SCLK D OUT LSR DI O I N5 i2so_lrck LRCK D OUT LSR DI O I M5 i2so_mclk MCLK D OUT LSR DI O I D IN ST DO I O IS2 data output data output from digital core to audio sub system, SDI and i2so_sdata are connected on the BGA I2S serial clock clock output from digital core to audio sub system, SCLK and isoi_sclk are connected on the BGA I2S left/right clock clock output from digital core to audio sub system, LRCK and i2so_lrck are connected on the BGA I2S master clock clock output from digital core to audio sub system, MCLK and i2so_mclk are connected on the BGA I2S Input M7 i2si_sdata SDO O i2si_sclk_out E3 D IO ST LSR i2si_sclk_in I O i2si_lrck_out D1 D IO ST LSR I i2si_lrck_in E4 i2si_mclk D OUT LSR C1 i2si_sdata_in D IN ST PD O I I2S data input data output from audio sub system to digital core, SDO and i2si_sdata are connected on the BGA I2S master serial clock serial clock output for external ADC if AS3525 is I2S master I2S slave serial clock serial clock input for external ADC if AS3525 is I2S slave I2S master, left/right clock left/right clock output for external ADC if AS3525 is I2S master I2S slave, left/right clock left/right clock input for external ADC if AS3525 is I2S master I2S master, master clock I2S data input data input from external audio ADC © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 177 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA224 Ball Name PAD Type spdif_data_in I/O Ball Description I SPDIF data input data input for SPDIF to I2S conversion O I used by the audio/PMU subsystem to interrupt the digital core, INTRQ and intrq are connected on the BGA I JTAG reset not Audio Subsystem IRQ N1 INTRQ intrq C2 jtag_trst_n DO D IN ST JTAG Debugging IF D IN ST PD A1 jtag_tms D IN ST PU I JTAG mode select B2 jtag_tck D IN ST PU I JTAG clock B1 jtag_tdi D IN ST PU I JTAG data input D3 jtag_tdo D IO ST PU LSR O JTAG data output External Memory IF G5 mpmc_addr[0] D OUT LSR LV O EXT. MEMORY address line B5 mpmc_addr[1] D OUT LSR LV O EXT. MEMORY address line L4 mpmc_addr[2] D OUT LSR LV O EXT. MEMORY address line A5 mpmc_addr[3] D OUT LSR LV O EXT. MEMORY address line K5 mpmc_addr[4] D OUT LSR LV O EXT. MEMORY address line D6 mpmc_addr[5] D OUT LSR LV O EXT. MEMORY address line F6 mpmc_addr[6] D OUT LSR LV O EXT. MEMORY address line C6 mpmc_addr[7] D OUT LSR LV O EXT. MEMORY address line E6 mpmc_addr[8] D OUT LSR LV O EXT. MEMORY address line A6 mpmc_addr[9] D OUT LSR LV O EXT. MEMORY address line H5 mpmc_addr[10] D OUT LSR LV O EXT. MEMORY address line B6 mpmc_addr[11] D OUT LSR LV O EXT. MEMORY address line J5 mpmc_addr[12] D OUT LSR LV O EXT. MEMORY address line D7 mpmc_addr[13] D OUT LSR LV O EXT. MEMORY address line E7 mpmc_addr[14] D OUT LSR LV O EXT. MEMORY address line C7 mpmc_addr[15] D OUT LSR LV O EXT. MEMORY address line F7 mpmc_addr[16] D OUT LSR LV O EXT. MEMORY address line A7 mpmc_addr[17] D OUT LSR LV O EXT. MEMORY address line G6 mpmc_addr[18] D OUT LSR LV O EXT. MEMORY address line B7 mpmc_addr[19] D OUT LSR LV O EXT. MEMORY address line H6 mpmc_addr[20] D OUT LSR LV O EXT. MEMORY address line O EXT. MEMORY clock enable0 used for SDRAM devices only EXT. MEMORY clock enable 1 used for SDRAM devices only EXT. MEMORY clock 0 used for SDRAM devices only EXT. MEMORY clock 1 used for SDRAM devices only EXT. MEMORY feedback clock used for SDRAM devices only EXT. MEMORY data mask 0 used for SDRAM devices and static memories EXT. MEMORY data mask 1 used for SDRAM devices and static memories EXT. MEMORY column address strobe not used for SDRAM devices only EXT. MEMORY dynamic memory chip select 0 not F8 mpmc_cke[0] D OUT LSR LV J6 mpmc_cke[1] D OUT LSR LV E8 mpmc_clk[0] D OUT LSR LV G7 mpmc_clk[1] D OUT LSR LV L5 mpmc_fbclkin D IO ST PD LSR LV D8 mpmc_dqm[0] D OUT LSR LV L6 mpmc_dqm[1] D OUT LSR LV A8 mpmc_cas_n D OUT LSR LV K6 mpmc_dycs_n[0] D OUT LSR LV O O O O O O O O © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 178 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA224 Ball Name PAD Type I/O Ball Description used for SDRAM devices only E9 mpmc_dycs_n[1] D OUT LSR LV J7 mpmc_ras_n D OUT LSR LV F9 mpmc_we_n D OUT LSR LV D9 mpmc_stcs_n[0] D OUT LSR LV L7 mpmc_stcs_n[1] D OUT LSR LV mpmc_bls_n[0] D OUT LSR LV mpmc_bls_n[1] D OUT LSR LV mpmc_oe_n D OUT LSR LV A9 K7 D10 O O O O O O O O EXT. MEMORY dynamic memory chip select 1 not used for SDRAM devices only EXT. MEMORY row address strobe not used for SDRAM devices only EXT. MEMORY write enable not used for SDRAM devices and static memories EXT. MEMORY static memory chip select 0 not used for static memory devices only EXT. MEMORY static memory chip select 0 not used for static memory devices only EXT. MEMORY byte lane select 0 not used for static memory devices only EXT. MEMORY byte lane select 1 not used for static memory devices only EXT. MEMORY output enable not used for static memory devices only EXT. MEMORY data line L8 mpmc_data[0] D IO ST PD LSR LV IO E10 mpmc_data[1] D IO ST PD LSR LV IO EXT. MEMORY data line L9 mpmc_data[2] D IO ST PD LSR LV IO EXT. MEMORY data line F10 mpmc_data[3] D IO ST PD LSR LV IO EXT. MEMORY data line K8 mpmc_data[4] D IO ST PD LSR LV IO EXT. MEMORY data line A10 mpmc_data[5] D IO ST PD LSR LV IO EXT. MEMORY data line J8 mpmc_data[6] D IO ST PD LSR LV IO EXT. MEMORY data line B10 mpmc_data[7] D IO ST PD LSR LV IO EXT. MEMORY data line H7 mpmc_data[8] D IO ST PD LSR LV IO EXT. MEMORY data line C10 mpmc_data[9] D IO ST PD LSR LV IO EXT. MEMORY data line G8 mpmc_data[10] D IO ST PD LSR LV IO EXT. MEMORY data line E11 mpmc_data[11] D IO ST PD LSR LV IO EXT. MEMORY data line G9 mpmc_data[12] D IO ST PD LSR LV IO EXT. MEMORY data line A11 mpmc_data[13] D IO ST PD LSR LV IO EXT. MEMORY data line J9 mpmc_data[14] D IO ST PD LSR LV IO EXT. MEMORY data line B11 mpmc_data[15] D IO ST PD LSR LV IO EXT. MEMORY data line DBOP G3 dbop_d[12] D IO ST PD LSR IO DISPLAY data input/output (high byte) H3 dbop_d[13] D IO ST PD LSR IO DISPLAY data input/output (high byte) A14 dbop_d[14] D IO ST PD LSR IO DISPLAY data input/output (high byte) C15 dbop_d[15] D IO ST PD LSR IO DISPLAY data input/output (high byte) USB 2.0 OTG F2 vdda33t PWP_VD_RDO_3V P USB 3.3V analog power supply for OTG transceiver block USB 3.3V analog ground supply for OTG transceiver block J1 vssa33t PWP_VS_RDO_3V P H2 vssa33t PWP_VS_RDO_3V P USB 3.3V analog ground supply for OTG transceiver block G2 vssa33t PWP_VS_RDO_3V P USB 3.3V analog ground supply for OTG transceiver block G1 usb_dp USB_ESD_5VT A USB D+ signal from USB cable H1 usb_dm USB_ESD_5VT A USB D- signal from USB cable K4 NC - K2 NC - J2 usb_rext ANA_BI_RXT_3V A test pin: must stay unconnected for normal operation mode test pin: must stay unconnected for normal operation mode USB external resistor connect analog signal to the external resistor for setting the bias © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 179 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA224 Ball Name PAD Type I/O Ball Description current of the USB 2.0 OTG PHY, voltage level is 1.1-1.3V J3 vdda33c L2 NC F3 VBUS usb_vbus PWP_VD_ANA_3V P USB 3.3V analog power supply for common block - test pin: must stay unconnected for normal operation mode USB20_VBUS_5VT_ AO USB 5V supply generated by the PMU subsystem, OTG VBUS and usb_vbus are connected on the BGA AIO USB mini receptacle Vbus Supply Balls A15 vdd_peri P P 3.3V peripheral power supply B9 vdd_mem P P 3.3V (2.5V) external memory power supply C9 vdd_mem P P 3.3V (2.5V) external memory power supply B15 vss_peri P P 3.3V peripheral ground supply B8 vss_mem P P 3.3V (2.5V) external memory ground supply C8 vss_mem P P 3.3V (2.5V) external memory ground supply K1 vdd_core P P 1.2V core power supply L1 vss_core P P 1.2V core ground supply DVDD P P I AFE Balls K3 audio/PMU subsystem digital power supply to be connected to QLDO2 (2.9V) power Up input L3 PwrUP DI PD N2 P_PVDD AI I 5 State program input of PVDD regulator P1 DVSS P P audio/PMU subsystem digital ground supply R1 XIN_24M AIO IO oscillator input 12-24MHz R2 XOUT_24M AIO IO oscillator output 12-24MHz P2 LIN2R AI I line input 2 right channel R3 LIN2L AI I line input 2 left channel P3 LIN1R AI I line input 1 right channel R4 LIN1L AI I line input 1 left channel N3 MSUP2 P P microphone supply 2 (2.95V) / remote input 2 P4 MIC2_N AI I microphone input 2N R5 MIC2_P AI I microphone input 2P R6 MIC1_P AI I microphone input 1P P5 MIC1_N AI I microphone input 1N P6 MSUP1 P P microphone supply 1 (2.95V) / remote input 1 N4 LOUTR AO O line output right channel / ear piece differential output N N7 LOUTL AO O line output left channel / ear piece differential output P N8 AVDD P P audio/PMU subsystem analog power supply P8 AGND AIO IO analog reference (AVDD/2) decoupling cap terminal (10uF) M8 VREF AIO IO R7 AVSS P P analog reference ( filtered AVDD) decoupling cap terminal (10uF) audio/PMU subsystem digital power supply N9 HPGND AIO IO O headphone amplifier reference decoupling cap terminal (100nF) headphone common GND output for DC-coupled speakers M9 HPCM AO N10 HPR AO O headphone output right channel N12 BVSS2 P P headphone amplifier ground supply N13 HPL AO O headphone output left channel N11 BGND P P speaker amplifier reference decoupling cap terminal (100nF) P9 BVDD P P audio/PMU subsystem power supply (max. 5.5V) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 180 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA224 R9 Ball Name LSPR PAD Type AO I/O O Ball Description speaker output right channel P7 BVSS P P speaker amplifier ground supply R8 BVSS P P speaker amplifier ground supply R10 LSPL AO O speaker output left channel P10 BVDD P P audio/PMU subsystem power supply (max. 5.5V) R11 UVDD AO O R12 PVDD AO O LDO6 Regulator Output fixed to 3.262V to be used for USB transceiver supply LDO3 Regulator Output programmed to 1.7 - 3.33V P11 BVDD AO O audio/PMU subsystem power supply (max. 5.5V) P12 IOVDD AO O LDO4 Regulator Output fixed to 3.109V R15 CVDD AO O M13 VBAT_1V P P charge pump output for digital core supply, programmed to 1.05 - 1.2V to be connected to vdd_core battery supply input for single cell application P15 CP_1V AIO IO CVDD charge pump flying cap N15 CN_1V AIO IO CVDD charge pump flying cap M15 VSS_1V P P CVDD charge pump ground supply M14 QLDO2 AO O L14 CP_5V AIO IO LDO2 regulator output fixed 2.9V to be connected to DVDD VBUS charge pump flying cap L13 CN_5V AIO IO VBUS charge pump flying cap L15 VSS_3V P P DCDC3V ground supply K15 SW_3V AO O DCDC3V switch terminal K14 SW_15V AO O DCDC15V switch terminal M12 VSS_15V P P DCDC15V ground supply M11 ISINK AO O DCDC15V load current sink terminal N14 CHG_IN AI I charger input P14 CHG_OUT AO O M10 BATTEMP AIO IO charger output programmable current (50-400mA) and voltage ( 3.9-4.25V) charger battery temperature sensor input (RNTC 100k) R14 XOUT_32k AIO IO 32kHz RTC oscillator crystal terminal R13 XIN_32k AIO IO 32kHz RTC oscillator crystal terminal P13 RVDD AO O RTC supply regulator output supplied via BVDD, programmed to 1.0-2.5V © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 181 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 8.3 CTBGA144 Package Drawings Figure 63 CTBGA144 Package Drawing AS3525B C22O22 AYWWZZZ Package Code AYYWWZZZ A Y WW ZZZ A … for PB free Year working week assembly/packaging Free choice 8.3.1 CTBGA144 Package Ball-out Figure 64 AS3525B Package Ball-out 1 2 3 4 5 6 7 8 9 10 11 12 A dbop_d12 dbop_d13 i2si_sdata_in xpc_2 xpa_6 xpa_7 vdd_peri vss_peri dbop_d14 naf_d_2 naf_d_1 naf_d_0 B jtag_tdi jtag_tck jtag_tdo xpc_3 xpa_4 xpa_5 ssp_fssout ssp_clkout dbop_d15 naf_d_3 naf_d_9 naf_d_8 C jtag_trst_n clk_ext jtag_tms xpc_4 xpa_2 xpa_3 ssp_rxd ssp_txd naf_d_4 naf_d_12 naf_d_11 naf_d_10 D usb_dp clk_sel xpc_7 xpc_1 xpa_0 xpa_1 naf_d_7 naf_d_6 naf_d_5 naf_d_15 naf_d_14 naf_d_13 E usb_dm tmsel xpc_6 xpc_0 naf_we_n naf_ce1_n naf_ce0_n naf_wp_n naf_ale naf_cle naf_re_n CHG_OUT F usb_vssa33 usb_vdda33 xpc_5 xpd_4 xpd_3 xpd_2 xpd_1 xpd_0 naf_bsy_n xpd_5 ISINK SW_15V G vss_core usb_rext id_dig xpb_2 xpb_1 xpb_0 xpd_7 xpd_6 CHG_IN CP_5V CN_5V SW_3V H XIN_32k vdd_core VBUS xpb_7 xpb_6 xpb_5 xpb_4 xpb_3 QLDO2 VSS_3V CP_1V CN_1V J XOUT_32k RVDD CSCL P_PVDD INTRQ PwrUP naf_ce2_n naf_ce3_n VSS_15V VSS_1V PVDD CVDD K DVDD CSDA XRES MSUP1 MSUP2 BATTEMP HPGND BGND BVSS2 VBAT_1V BVDD BVDD L XOUT_24M AVDD VREF MIC1_N MIC2_N LIN2L LIN1L LOUTL BVSS HPR HPL IOVDD M XIN_24M AVSS AGND MIC1_P MIC2_P LIN2R LIN1R LOUTR HPCM LSPR LSPL UVDD © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 182 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 8.3.2 CTBGA144 Ball List Table 162 CTBGA144 Ball List Ball Nr. BGA144 Ball Name PAD Type C2 XRES resetext_n clk_ext DO D IN ST D IN ST PD D2 clk_sel D IN ST PD E2 tmsel D IN ST PD G3 id_dig D IN ST (PU) K3 I/O Ball Description O I I XRES is generated by the PMU subsystem and connected to reset input (active low) on the BGA external clock input (10-26MHz) I clock select 0 (low): clock from internal oscillator is used 1 (high): clock from pad clk_ext is used test mode select For testing purpose only, has to be set to “0”. USB mini receptacle identifier Has to be connected to USB jack ID pin. I I Port A D5 xpa[0] D IO ST PD LSR IO GPIO IO, Port A D6 xpa[1] D IO ST PD LSR IO GPIO IO, Port A C5 xpa[2] D IO ST PD LSR IO GPIO IO, Port A C6 xpa[3] D IO ST PD LSR IO GPIO IO, Port A B5 xpa[4] D IO ST PD LSR IO GPIO IO, Port A B6 xpa[5] D IO ST PD LSR IO GPIO IO, Port A A5 xpa[6] D IO ST PD LSR IO GPIO IO, Port A A6 xpa[7] D IO ST PD LSR IO GPIO IO, Port A IO GPIO IO, Port B I Port B / DISPLAY / UART xpb[0] G6 G5 G4 H8 dbop_c0 O static memory chip memory width setting for boot loader 0: 8 bit data bus 1: 16 bit data bus The value is latched at reset. DISPLAY control output xpb[1] IO GPIO IO, Port B I mpmc_stcs1mw[0 D IO ST PD LSR ]* dbop_c1 O static memory chip select polarity setting for boot loader 0: active LOW chip select 1: active high chip select The value is latched at reset. DISPLAY control output xpb[2] IO GPIO IO, Port B I mpmc_stcs1pol* D IO ST PD LSR dbop_c2 O static memory byte lane polarity setting for boot loader 0: HIGH for reads, LOW for writes, used for we_n access 1: LOW for reads, LOW for writes, used for upper and lower byte access The value is latched at reset. DISPLAY control output xpb[3] IO GPIO IO, Port B I O test mode configuration (for testing purpose only !!!) The value is latched at reset. DISPLAY control output IO GPIO IO, Port B IO DISPLAY data input/output (high byte) IO GPIO IO, Port B IO DISPLAY data input/output (high byte) IO GPIO IO, Port B mpmc_stcs1pb* D IO ST PD LSR mpmc_rel1config* D IO ST PD LSR dbop_c3 H7 H6 H5 xpb[4] dbop_d[8] xpb[5] dbop_d[9] xpb[6] D IO ST PD LSR D IO ST PD LSR D IO ST PU LSR © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 183 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA144 Ball Name PAD Type Ball Description uart_rxd I UART receive line dbop_d[10] IO DISPLAY data input/output (high byte) IO GPIO IO, Port B O UART transmit line IO DISPLAY data input/output (high byte) xpb[7] H4 I/O uart_txd D IO ST PU LSR dbop_d[11] Port C / DISPLAY / 2-WIRE SERIAL xpc[0] E4 D4 A4 IntBootSel* F3 IO IO GPIO IO, Port C boot_sel[0] I BOOT LOADER type select input dbop_d[1] IO DISPLAY data input/output (low byte) xpc[2] IO GPIO IO, Port C I BOOT LOADER type select input IO DISPLAY data input/output (low byte) boot_sel[1] D IO ST PD LSR D IO ST PD LSR IO GPIO IO, Port C I BOOT LOADER type select input dbop_d[3] IO DISPLAY data input/output (low byte) xpc[4] IO GPIO IO, Port C boot_sel[2] dbop_d[4] xpc[5] dbop_d[5] cmd_ms_sck dbop_d[6] D IO ST PD LSR D IO ST PD LSR D IO ST PD LSR cmd_ms_sda IO DISPLAY data input/output (low byte) IO GPIO IO, Port C IO DISPLAY data input/output (low byte) IO D IO ST PU LSR IO IO xpc[7] D3 BOOT LOADER source select input 1: internal ROM 0: external ROM/Flash DISPLAY data input/output (low byte) xpc[1] xpc[6] E3 I dbop_d[0] xpc[3] C4 GPIO IO, Port C D IO ST PD LSR dbop_d[2] B4 IO IO D IO ST PU LSR dbop_d[7] GPIO IO, Port C 2-WIRE SERIAL master/slave clock line DISPLAY data input/output (low byte) GPIO IO, Port C IO 2-WIRE SERIAL master/slave data line IO DISPLAY data input/output (low byte) Port D / SD Card / Memory Stick F8 F7 xpd[0] IO GPIO IO, Port D mci_dat[0] IO MMC/SD data line ms_sdio[0] IO MEMORY STICK data line xpd[1] IO GPIO IO, Port D IO MMC/SD data line IO MEMORY STICK data line mci_dat[1] D IO ST LSR D IO ST LSR ms_sdio[1] xpd[2] F6 F5 F4 IO GPIO IO, Port D IO MMC/SD data line ms_sdio[2] IO MEMORY STICK data line xpd[3] IO GPIO IO, Port D mci_dat[2] mci_dat[3] D IO ST LSR IO MMC/SD data line ms_sdio[3] IO MEMORY STICK data line xpd[4] IO GPIO IO, Port D O MMC/SD command line O MEMORY STICK clock line IO GPIO IO, Port D O MMC/SD clock line mci_cmd D IO ST LSR D IO ST LSR ms_sclk F10 xpd[5] mci_clk D IO ST LSR © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 184 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA144 G8 Ball Name PAD Type Ball Description ms_bs O MEMORY STICK bus state xpd[6] IO GPIO IO, Port D I MMC/SD feedback clock I MEMORY STICK feedback clock mci_fbclk D IO ST LSR ms_fbclk G7 I/O xpd[7] mci_rod D IO ST LSR IO GPIO IO, Port D O MMC/SD resistor open drain control O 2-WIRE SERIAL audio master clock line used for controlling the audio/PMU sub system 2-WIRE SERIAL audio master data line used for controlling the audio/PMU sub system 2-WIRE SERIAL Audio Master J3 CSCL D IO ST PU LSR K2 CSDA D IO ST PU LSR O Serial Synchronous Port B7 B8 ssp_fssout ssp_fssin ssp_clkout ssp_clkin D IO ST PU LSR D IO ST PU LSR O SSP master, frame or slave select I SSP slave, frame select O SSP master, clock line I SSP slave, clock line C7 ssp_rxd D IO ST PU LSR I SSP receive data input C8 ssp_txd D IO ST PU LSR O SSP transmit data output IO NAND FLASH data line (low byte) NandFlash / IDE A12 naf_d[0] D IO ST PD LSR A11 naf_d[1] D IO ST PD LSR IO NAND FLASH data line (low byte) A10 naf_d[2] D IO ST PD LSR IO NAND FLASH data line (low byte) B10 naf_d[3] D IO ST PD LSR IO NAND FLASH data line (low byte) C9 naf_d[4] D IO ST PD LSR IO NAND FLASH data line (low byte) D9 naf_d[5] D IO ST PD LSR IO NAND FLASH data line (low byte) D8 naf_d[6] D IO ST PD LSR IO NAND FLASH data line (low byte) D7 naf_d[7] D IO ST PD LSR IO NAND FLASH data line (low byte) B12 naf_d[8] D IO ST PD LSR IO NAND FLASH data line (high byte) B11 naf_d[9] D IO ST PD LSR IO NAND FLASH data line (high byte) C12 naf_d[10] D IO ST PD LSR IO NAND FLASH data line (high byte) C11 naf_d[11] D IO ST PD LSR IO NAND FLASH data line (high byte) C10 naf_d[12] D IO ST PD LSR IO NAND FLASH data line (high byte) D12 naf_d[13] D IO ST PD LSR IO NAND FLASH data line (high byte) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 185 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA144 D11 D10 E10 E9 E8 E7 E6 J7 J8 E5 E11 F9 Ball Name naf_d[14] naf_d[15] naf_cle naf_ale naf_wp_n naf_ce0_n naf_ce1_n naf_ce2_n naf_ce3_n naf_we_n naf_re_n naf_bsy_n PAD Type D IO ST PD LSR D IO ST PD LSR D IO ST LSR D IO ST LSR D IO ST PD LSR D IO ST LSR D IO ST LSR D IO ST LSR D IO ST LSR D IO ST LSR D IO ST LSR D IO ST LSR I/O Ball Description IO NAND FLASH data line (high byte) IO NAND FLASH data line (high byte) O NAND FLASH command latch enable O NAND FLASH address latch enable O NAND FLASH write protect not O NAND FLASH chip enable O NAND FLASH chip enable O NAND FLASH chip enable O NAND FLASH chip enable O NAND FLASH write enable not O NAND FLASH read enable not I NAND FLASH ready / busy not I I2S data input data input from external audio ADC SPDIF data input data input for SPDIF to I2S conversion I2S Input i2si_sdata_in A3 D IN ST PD spdif_data_in I Audio Subsystem IRQ J5 INTRQ intrq DO D IN ST O I used by the audio/PMU subsystem to interrupt the digital core, INTRQ and intrq are connected on the BGA C1 jtag_trst_n I JTAG reset not C3 jtag_tms D IN ST PU I JTAG mode select B2 jtag_tck D IN ST PU I JTAG clock B1 jtag_tdi D IN ST PU I JTAG data input B3 jtag_tdo D IO ST PU LSR O JTAG data output JTAG Debugging IF D IN ST PD DBOP A1 dbop_d[12] D IO ST PD LSR IO DISPLAY data input/output (high byte) A2 dbop_d[13] D IO ST PD LSR IO DISPLAY data input/output (high byte) A9 dbop_d[14] D IO ST PD LSR IO DISPLAY data input/output (high byte) B9 dbop_d[15] D IO ST PD LSR IO DISPLAY data input/output (high byte) PWP_VD_ ANA_3V PWP_VS_ ANA_3V P USB 3.3V analog power supply for common block P USB 3.3V analog ground supply for common block USB 2.0 OTG F2 vdda33 F1 vssa33 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 186 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA144 Ball Name PAD Type I/O Ball Description D1 usb_dp USB_ESD_5VT A USB D+ signal from USB cable E1 usb_dm USB_ESD_5VT A USB D- signal from USB cable G2 usb_rext ANA_BI_RXT_3V A H3 VBUS usb_vbus USB external resistor connect analog signal to the external resistor for setting the bias current of the USB 2.0 OTG PHY, voltage level is 1.1-1.3V USB20_VBUS_5V AO USB 5V supply generated by the PMU subsystem, T_OTG VBUS and usb_vbus are connected on the BGA AIO USB mini receptacle Vbus Supply Balls A7 vdd_peri P P 3.3V peripheral power supply A8 vss_peri P P 3.3V peripheral ground supply H2 vdd_core P P G1 vss_core P P 1.2V core power supply Note: This PIN has to be connected to CVDD! 1.2V core ground supply DVDD P P J6 PwrUP DI PD I audio/PMU subsystem digital power supply to be connected to QLDO2 (2.9V) power Up input J4 P_PVDD AI I 5 State program input of PVDD regulator M1 XIN_24M AIO IO oscillator input 12-24MHz L1 XOUT_24M AIO IO oscillator output 12-24MHz AFE Balls K1 M6 LIN2R AI I line input 2 right channel L6 LIN2L AI I line input 2 left channel M7 LIN1R AI I line input 1 right channel L7 LIN1L AI I line input 1 left channel K5 MSUP2 P P microphone supply 2 (2.95V) / remote input 2 L5 MIC2_N AI I microphone input 2N M5 MIC2_P AI I microphone input 2P M4 MIC1_P AI I microphone input 1P L4 MIC1_N AI I microphone input 1N K4 MSUP1 P P microphone supply 1 (2.95V) / remote input 1 M8 LOUTR AO O line output right channel / ear piece differential output N L8 LOUTL AO O line output left channel / ear piece differential output P L2 AVDD P P audio/PMU subsystem analog power supply M3 AGND AIO IO analog reference (AVDD/2) decoupling cap terminal (10uF) L3 VREF AIO IO M2 AVSS P P analog reference ( filtered AVDD) decoupling cap terminal (10uF) audio/PMU subsystem digital power supply K7 HPGND AIO IO headphone amplifier reference decoupling cap terminal (100nF) M9 HPCM AO O headphone common GND output for DC-coupled speakers L10 HPR AO O headphone output right channel K9 BVSS2 P P headphone amplifier ground supply L11 HPL AO O headphone output left channel K8 BGND P P speaker amplifier reference decoupling cap terminal (100nF) K11 BVDD P P audio/PMU subsystem power supply (max. 5.5V) M10 LSPR AO O speaker output right channel L9 BVSS P P speaker amplifier ground supply M11 LSPL AO O speaker output left channel K12 BVDD P P audio/PMU subsystem power supply (max. 5.5V) © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 187 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential Ball Nr. BGA144 Ball Name PAD Type AO I/O O Ball Description M12 UVDD J11 PVDD AO O LDO6 Regulator Output fixed to 3.262V to be used for USB transceiver supply LDO3 Regulator Output programmed to 1.7 - 3.33V L12 IOVDD AO O LDO4 Regulator Output fixed to 3.109V J12 CVDD AO O K10 VBAT_1V P P charge pump output for digital core supply, programmed to 1.05 - 1.2V Note: This PIN has to be connected to vdd_core! battery supply input for single cell application H11 CP_1V AIO IO CVDD charge pump flying cap H12 CN_1V AIO IO CVDD charge pump flying cap J10 VSS_1V P P CVDD charge pump ground supply H9 QLDO2 AO O G10 CP_5V AIO IO LDO2 regulator output fixed 2.9V to be connected to DVDD VBUS charge pump flying cap G11 CN_5V AIO IO VBUS charge pump flying cap H10 VSS_3V P P DCDC3V ground supply G12 SW_3V AO O DCDC3V switch terminal F12 SW_15V AO O DCDC15V switch terminal J9 VSS_15V P P DCDC15V ground supply F11 ISINK AO O DCDC15V load current sink terminal G9 CHG_IN AI I charger input E12 CHG_OUT AO O K6 BATTEMP AIO IO charger output programmable current (50-400mA) and voltage ( 3.9-4.25V) charger battery temperature sensor input (RNTC 100k) J1 XOUT_32k AIO IO 32kHz RTC oscillator crystal terminal H1 XIN_32k AIO IO 32kHz RTC oscillator crystal terminal J2 RVDD AO O RTC supply regulator output supplied via BVDD, programmed to 1.0-2.5V © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 188 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 8.4 Pad Cell Description 8.4.1 Digital Pads 8.4.1.1 D IN ST 8.4.1.2 D IN PD ST Figure 66 Digital Input with Schmitt Trigger and Pull-Down Figure 65 Digital Input with Schmitt Trigger Schmitt PAD 8.4.1.3 Schmitt C D IN PU ST PAD C 8.4.1.4 Figure 67 Digital Input with Schmitt Trigger and Pull-Up D IN (PU) Figure 68 Digital Input with enable controlled Pull-Up Schmitt PAD C REN PAD 8.4.1.5 D OUT LSR 8.4.1.6 Figure 69 Digital Output with Limited Slew Rate I C D IO ST LSR Figure 70 Digital Schmitt Trigger Input and Limited Slew Rate Output PAD Schmitt C I PAD © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 189 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 8.4.1.7 D IO ST PU LSR 8.4.1.8 Figure 71 Digital Schmitt Trigger Input with Pull-Up and Limited Slew Rate Output D IO ST PD LSR Figure 72 Digital Schmitt Trigger Input with Pull-Down and Limited Slew Rate Output Schmitt Schmitt C C I I PAD 8.4.1.9 D OUT LSR LV 8.4.1.10 D IO ST PD LSR LV Figure 73 Digital Output with Limited Slew Rate (low voltage) I PAD Figure 74 Digital Schmitt Trigger Input with Pull-Down and Limited Slew Rate Output (low voltage) PAD Schmitt C I 9 Appendix 9.1 Memory MAP PAD ARM922T provides 32-bit address to access the peripherals and memory. With this 32-bit address ARM922T can access up to 4 Giga Bytes of memory. Cocoa does not use the complete 4 GB address space. Address 0x0000_0000 is mapped to internal ROM or External Memory interface based on the boot ROM selection by the external input pin (Port C, xpc[0] = intBootSel) Pin intBootSel=1 at startup selects the internal ROM, intBootSel = 0 selects the external memory. The address range starting at 0x0000_0000 is also mapped to internal RAM upon setting of the remap bit. This remap allows the user to select either RAM or ROM at 0x0000_0000. Table 163 Address Map S.No . Start (Base) Address End Address Actual Block Size Peripheral Comment AHB Blocks 0x0000_0000 0x0001_FFFF 128 KByte Internal ROM 0x0000_0000 0x003F_FFFF 4 MB 0x0000_0000 0x0100_0000 0x1000_0000 0x0004_FFFF 0x0FFF_FFFF 0x103F_FFFF 320 KByte External Memory IF (MPMC Bank1 – Ext Flash or Ext ROM) Embedded 1T-RAM Reserved External Memory IF (MPMC Bank1 – Ext Flash or Ext ROM) 4 MB Remap = 0 and IntBootSel = 1 Remap = 0 and IntBootSel = 0 Remap = 1 Aliased © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 190 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential S.No . Start (Base) Address End Address Actual Block Size 0x1100_0000 0x2000_0000 0x1FFF_FFFF 0x203F_FFFF 4 MB 0x2100_0000 0x3000_0000 0x2FFF_FFFF 0x3FFF_FFFF 256 MB 0x4000_0000 0x4FFF_FFFF 256 MB 0x5000_0000 0x8000_0000 0x8002_0000 0x8100_0000 0x8105_0000 0xC000_0000 0xC002_0000 0xC100_0000 0xC105_0000 0xC600_0000 0xC601_0000 0xC602_0000 0xC603_0000 0xC604_0000 0xC605_0000 0x7FFF_FFFF 0x8001_FFFF 0x80FF_FFFF 0x8104_FFFF 0xBFFF_FFFF 0xC001_FFFF 0xC0FF_FFFF 0xC104_FFFF 0xC5FF_FFFF 0xC600_FFFF 0xC601_FFFF 0xC602_FFFF 0xC603_FFFF 0xC604_FFFF 0xC605_FFFF 0xC606_0000 0xC607_0000 0xC606_FFFF 0xC7FF_FFFF 128 KByte 320 KByte 128 KByte 320 KByte Few Few Few Few Few Few 4 KByte Peripheral Reserved External Memory IF (MPMC Bank2 – External LCD Controller) Reserved External Memory IF (MPMC Bank 4 – SDRAM) External Memory If (MPMC Bank5 – SDRAM) Reserved Internal ROM Reserved Embedded 1T-RAM Reserved Internal ROM Reserved Embedded 1T-RAM Reserved USB2.0 Slave VIC DMAC Slave ExtMemIFSlave MemoryStick Slave CompactFlash/IDE Slave ARM922T Slave Reserved Comment Aliased Aliased Aliased Aliased APB blocks 9.2 0xC800_0000 0xC800_FFFF Few 0xC801_0000 0xC802_0000 0xC803_0000 0xC804_0000 0xC805_0000 0xC806_0000 0xC807_0000 0xC808_0000 0xC809_0000 0xC80A_0000 0xC80B_0000 0xC80C_0000 0xC80D_0000 0xC80E_0000 0xC80F_0000 0xC810_0000 0xC811_0000 0xC812_0000 0xC813_0000 0xC801_FFFF 0xC802_FFFF 0xC803_FFFF 0xC804_FFFF 0xC805_FFFF 0xC806_FFFF 0xC807_FFFF 0xC808_FFFF 0xC809_FFFF 0xC80A_FFFF 0xC80B_FFFF 0xC80C_FFFF 0xC80D_FFFF 0xC80E_FFFF 0xC80F_FFFF 0xC810_FFFF 0xC811_FFFF 0xC812_FFFF 0xC813_FFFF Few Few Few Few Few Few Few Few Few Few Few Few Few Few Few Few Few Nand Flash / Smart Media Interface BistManager SD-MCI Reserved Timer Watchdog Timer I2C Master/Slave I2C Audio Master SSP I2S IN Interface I2S OUT Interface GPIO A GPIO B GPIO C GPIO D Clock Generation Unit Chip Control Unit Debug UART DBOP reserved Register definitions This section gives a short overview of all module registers. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 191 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 9.2.1 Base Address definitions Each module register block starts at a specific base address. Table 164 Base Addresses REGISTER Name AS3525_RAM_BASE AS3525_USB_BASE AS3525_VIC_BASE AS3525_DMAC_BASE AS3525_EXTMEM_ITF_BASE AS3525_MEMSTICK_BASE AS3525_CF_IDE_BASE AS3525_NAND_FLASH_BASE AS3525_BIST_MANAGER_BASE AS3525_SD_MCI_BASE AS3525_TIMER_BASE AS3525_WDT_BASE AS3525_I2C_MS_BASE AS3525_I2C_AUDIO_BASE AS3525_SSP_BASE AS3525_I2SIN_BASE AS3525_I2SOUT_BASE AS3525_GPIO1_BASE AS3525_GPIO2_BASE AS3525_GPIO3_BASE AS3525_GPIO4_BASE AS3525_CGU_BASE AS3525_CCU_BASE AS3525_UART_BASE AS3525_DBOP_BASE Register Address 0x00000000 0xC6000000 0xC6010000 0xC6020000 0xC6030000 0xC6040000 0xC6050000 0xC8000000 0xC8010000 0xC8020000 0xC8040000 0xC8050000 0xC8060000 0xC8070000 0xC8080000 0xC8090000 0xC80A0000 0xC80B0000 0xC80C0000 0xC80D0000 0xC80E0000 0xC80F0000 0xC8100000 0xC8110000 0xC8120000 © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 192 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 10 Ordering Information Table 165 ordering information Number AS3525A C21O20 TRA AS3525A C21O20T&R AS3525B C21O20TRA AS3525B C21O20T&R AS3525A C22O22 TRA AS3525A C22O22T&R AS3525B C22O22TRA AS3525B C22O22T&R Package Type CTBGA CTBGA CTBGA CTBGA CTBGA CTBGA CTBGA CTBGA 224 224 144 144 224 224 144 144 Delivery Form Tray Tape and Reel Tray Tape and Reel Tray Tape and Reel Tray Tape and Reel Description don’t don’t don’t don’t use use use use for for for for new new new new design design design design starts starts starts starts AS3525P V D Where V = Version P = Package Type: A: CTBGA 224, Thin ChipArray Ball Grid Array, 13x13mm package size, 0.8mm ball pitch B: CTBGA 144, Thin ChipArray Ball Grid Array, 10x10mm package size, 0.8mm ball pitch D = Delivery Form: TRA = Tray T&R = Tape and Reel All package variants are Pb-free/ RoHS package types. © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 193 - 194 AS3525-A/-B C22O22 Data Sheet, Confidential 11 Copyright Copyright © 2005-2007, austriamicrosystems AG, Schloss Premstaetten, 8141 Unterpremstaetten, Austria-Europe. Trademarks Registered ®. All rights reserved. The material herein may not be reproduced, adapted, merged, translated, stored, or used without the prior written consent of the copyright owner. All products and companies mentioned are trademarks of their respective companies. 12 Disclaimer Devices sold by austriamicrosystems AG are covered by the warranty and patent identification provisions appearing in its Term of Sale. austriamicrosystems AG makes no warranty, express, statutory, implied, or by description regarding the information set forth herein or regarding the freedom of the described devices from patent infringement. austriamicrosystems AG reserves the right to change specifications and prices at any time and without notice. Therefore, prior to designing this product into a system, it is necessary to check with austriamicrosystems AG for current information. This product is intended for use in normal commercial applications. Applications requiring extended temperature range, unusual environmental requirements, or high reliability applications, such as military, medical life-support or lifesustaining equipment are specifically not recommended without additional processing by austriamicrosystems AG for each application. The information furnished here by austriamicrosystems AG is believed to be correct and accurate. However, austriamicrosystems AG shall not be liable to recipient or any third party for any damages, including but not limited to personal injury, property damage, loss of profits, loss of use, interruption of business or indirect, special, incidental or consequential damages, of any kind, in connection with or arising out of the furnishing, performance or use of the technical data herein. No obligation or liability to recipient or any third party shall arise or flow out of austriamicrosystems AG rendering of technical or other services. 13 Contact Information austriamicrosystems AG Business Unit Communications A 8141 Schloss Premstätten, Austria T. +43 (0) 3136 500 0 F. +43 (0) 3136 5692 [email protected] For Sales Offices, Distributors and Representatives, please visit: http://www.austriamicrosystems.com © 2005-2009, austriamicrosystems AG, 8141 Unterpremstaetten, Austria-Europe. All Rights Reserved. www.austriamicrosystems.com Revision 1.13 194 - 194