Features • Incorporates the ARM926EJ-S™ ARM® Thumb® Processor • • • • • • • • • – DSP instruction Extensions, ARM Jazelle® Technology for Java® Acceleration – 8 Kbytes Data Cache, 16 Kbytes Instruction Cache, Write Buffer – 200 MIPS at 180 MHz – Memory Management Unit – EmbeddedICE™, Debug Communication Channel Support Additional Embedded Memories – One 32-Kbyte Internal ROM, Single-cycle Access at Maximum Matrix Speed – One 32-Kbyte (for AT91SAM9XE256 and AT91SAM9XE512) or 16-Kbyte (for AT91SAM9XE128) Internal SRAM, Single-cycle Access at Maximum Matrix Speed – 128, 256 or 512 Kbytes of Internal High-speed Flash for AT91SAM9XE128, AT91SAM9XE256 or AT91SAM9XE512 Respectively. Organized in 256, 512 or 1024 Pages of 512 Bytes Respectively. • 128-bit Wide Access • Fast Read Time: 45 ns • Page Programming Time: 4 ms, Including Page Auto-erase, Full Erase Time: 10 ms • 10,000 Write Cycles, 10 Years Data Retention, Page Lock Capabilities, Flash Security Bit Enhanced Embedded Flash Controller (EEFC) – Interface of the Flash Block with the 32-bit Internal Bus – Increases Performance in ARM and Thumb Mode with 128-bit Wide Memory Interface External Bus Interface (EBI) – Supports SDRAM, Static Memory, ECC-enabled NAND Flash and CompactFlash™ USB 2.0 Full Speed (12 Mbits per second) Device Port – On-chip Transceiver, 2,688-byte Configurable Integrated DPRAM USB 2.0 Full Speed (12 Mbits per second) Host Single Port in the 208-pin PQFP Device and Double Port in 217-ball LFBGA Device – Single or Dual On-chip Transceivers – Integrated FIFOs and Dedicated DMA Channels Ethernet MAC 10/100 Base-T – Media Independent Interface or Reduced Media Independent Interface – 128-byte FIFOs and Dedicated DMA Channels for Receive and Transmit Image Sensor Interface – ITU-R BT. 601/656 External Interface, Programmable Frame Capture Rate – 12-bit Data Interface for Support of High Sensibility Sensors – SAV and EAV Synchronization, Preview Path with Scaler, YCbCr Format Bus Matrix – Six 32-bit-layer Matrix – Remap Command Fully-featured System Controller, including – Reset Controller, Shutdown Controller – Four 32-bit Battery Backup Registers for a Total of 16 Bytes – Clock Generator and Power Management Controller – Advanced Interrupt Controller and Debug Unit – Periodic Interval Timer, Watchdog Timer and Real-time Timer AT91 ARM Thumb Microcontrollers AT91SAM9XE128 AT91SAM9XE256 AT91SAM9XE512 Preliminary Summary NOTE: This is a summary document. The complete document is available on the Atmel website at www.atmel.com. 6254CS–ATARM–08-Jan-10 • Reset Controller (RSTC) – Based on a Power-on Reset Cell, Reset Source Identification and Reset Output Control • Clock Generator (CKGR) • • • • • • • • • • • • • • • • 2 – Selectable 32,768 Hz Low-power Oscillator or Internal Low Power RC Oscillator on Battery Backup Power Supply, Providing a Permanent Slow Clock – 3 to 20 MHz On-chip Oscillator, One Up to 240 MHz PLL and One Up to 100 MHz PLL Power Management Controller (PMC) – Very Slow Clock Operating Mode, Software Programmable Power Optimization Capabilities – Two Programmable External Clock Signals Advanced Interrupt Controller (AIC) – Individually Maskable, Eight-level Priority, Vectored Interrupt Sources – Three External Interrupt Sources and One Fast Interrupt Source, Spurious Interrupt Protected Debug Unit (DBGU) – 2-wire UART and support for Debug Communication Channel, Programmable ICE Access Prevention – Mode for General Purpose Two-wire UART Serial Communication Periodic Interval Timer (PIT) – 20-bit Interval Timer Plus 12-bit Interval Counter Watchdog Timer (WDT) – Key-protected, Programmable Only Once, Windowed 16-bit Counter Running at Slow Clock Real-Time Timer (RTT) – 32-bit Free-running Backup Counter Running at Slow Clock with 16-bit Prescaler One 4-channel 10-bit Analog to Digital Converter Three 32-bit Parallel Input/Output Controllers (PIOA, PIOB, PIOC,) – 96 Programmable I/O Lines Multiplexed with up to Two Peripheral I/Os – Input Change Interrupt Capability on Each I/O Line – Individually Programmable Open-drain, Pull-up Resistor and Synchronous Output Peripheral DMA Controller Channels (PDC) Two-slot Multimedia Card Interface (MCI) – SDCard/SDIO and MultiMediaCard™ Compliant – Automatic Protocol Control and Fast Automatic Data Transfers with PDC One Synchronous Serial Controllers (SSC) – Independent Clock and Frame Sync Signals for Each Receiver and Transmitter – I²S Analog Interface Support, Time Division Multiplex Support – High-speed Continuous Data Stream Capabilities with 32-bit Data Transfer Four Universal Synchronous/Asynchronous Receiver Transmitters (USART) – Individual Baud Rate Generator, IrDA® Infrared Modulation/Demodulation, Manchester Encoding/Decoding – Support for ISO7816 T0/T1 Smart Card, Hardware Handshaking, RS485 Support – Full Modem Signal Control on USART0 One 2-wire UART Two Master/Slave Serial Peripheral Interface (SPI) – 8- to 16-bit Programmable Data Length, Four External Peripheral Chip Selects – Synchronous Communications Two Three-channel 16-bit Timer/Counters (TC) – Three External Clock Inputs, Two Multi-purpose I/O Pins per Channel – Double PWM Generation, Capture/Waveform Mode, Up/Down Capability – High-Drive Capability on Outputs TIOA0, TIOA1, TIOA2 Two Two-wire Interfaces (TWI) – Master, Multi-master and Slave Mode Operation – General Call Supported in Slave Mode – Connection to PDC Channel to Optimize Data Transfers in Master Mode Only AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary • IEEE® 1149.1 JTAG Boundary Scan on All Digital Pins • Required Power Supplies: – 1.65V to 1.95V for VDDBU, VDDCORE and VDDPLL – 1.65V to 3.6V for VDDIOP1 (Peripheral I/Os) – 3.0V to 3.6V for VDDIOP0 and VDDANA (Analog-to-digital Converter) – Programmable 1.65V to 1.95V or 3.0V to 3.6V for VDDIOM (Memory I/Os) • Available in a 208-pin PQFP Green and a 217-ball LFBGA Green Package 1. AT91SAM9XE128/256/512 Description The AT91SAM9XE128/256/512 is based on the integration of an ARM926EJ-S processor with fast ROM and RAM, 128, 256 or 512 Kbytes of Flash and a wide range of peripherals. The embedded Flash memory can be programmed in-system via the JTAG-ICE interface or via a parallel interface on a production programmer prior to mounting. Built-in lock bits a security bit and MMU protect the firmware from accidental overwrite and preserve its confidentiality. The AT91SAM9XE128/256/512 embeds an Ethernet MAC, one USB Device Port, and a USB Host Controller. It also integrates several standard peripherals, like six UARTs, SPI, TWI, Timer Counters, Synchronous Serial Controller, ADC and a MultiMedia/SD Card Interface. The AT91SAM9XE128/256/512 system controller includes a reset controller capable of managing the power-on sequence of the microcontroller and the complete system. Correct device operation can be monitored by a built-in brownout detector and a watchdog running off an integrated RC oscillator. The AT91SAM9XE128/256/512 is architectured on a 6-layer matrix, allowing a maximum internal bandwidth of six 32-bit buses. It also features an External Bus Interface capable of interfacing with a wide range of memory devices. The pinout and ball-out are fully compatible with the AT91SAM9260 with the exception that the pin BMS is replaced by the pin ERASE. 3 6254CS–ATARM–08-Jan-10 2. AT91SAM9XE128/256/512 Block Diagram The block diagram shows all the features for the 217-LFBGA package. Some functions are not accessible in the 208-PQFP package and the unavailable pins are highlighted in “Multiplexing on PIO Controller A” on page 36, “Multiplexing on PIO Controller B” on page 37, “Multiplexing on PIO Controller C” on page 38. The USB Host Port B is also not available. Table 2-1 on page 4 defines all the multiplexed and not multiplexed pins not available in the 208-PQFP package. Table 2-1. 4 Unavailable Signals in 208-pin PQFP Device PIO Peripheral A Peripheral B - HDPB - - HDMB - PA30 SCK2 RXD4 PA31 SCK0 TXD4 PB12 TWD1 ISI_D10 PB13 TWCK1 ISI_D11 PC2 AD2 PCK1 PC3 AD3 SPI1_NPCS3 PC12 IRQ0 NCS7 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 NRST POR VDDCORE MCI RSTC SHDC RTT PDC TWI0 TWI1 4GPREG PIT PMC PDC BOD POR OSC RC WDT OSC PLLB PLLA PDC DBGU AIC System Controller SLAVE VDDBU SHDN WKUP OSCSEL XIN32 XOUT32 XIN XOUT PLLRCA DRXD DTXD PCK0-PCK1 FIQ IRQ0-IRQ2 TST Filter M CD B 0M CD M CD MC B3 A0 CD -M B C M DA CC 3 D M A CC K PIOC PIOB PIOA PDC USART0 USART1 USART2 USART3 USART4 NT R TD ST TDI TMO TC S RTK CK E L In-Circuit Emulator MMU TC0 TC1 TC2 ROM 32 Kbytes Bus Interface PDC SPI0 SPI1 Flash 128, 256 or 512 Kbytes I ICache 16 Kbytes TC3 TC4 TC5 Fast SRAM 16 or 32 Kbytes D DCache 8 Kbytes ARM926EJ-S Processor SPI0_, SPI1_ AS APB SE JTAG Selection and Boundary Scan JT AG SSC PDC FIFO DMA 4-channel 10-bit ADC PDC Peripheral Bridge Transceiver USB Device DPRAM DMA DMA ECC Controller Static Memory Controller SDRAM Controller CompactFlash NAND Flash EBI USB OHCI Transc. HD P HD B M B Image Sensor Interface Transc. IS I _M IS CK I_ IS PC I _ K I D S I_ O-I V IS SY SI_ I_ N D7 H SY C NC H D HD PA M A 24-channel Peripheral DMA FIFO 10/100 Ethernet MAC 6-layer Matrix NP NPCS NPCS3 NPCS2 C 1 SP S0 MC OK TC M SI IS L O TI K0 O -T T A C I O 0-T LK TC B0 IOA2 L -T 2 TI K3 IOB O TI A3 TC 2 O -T LK B I 5 3 -T OA IO 5 B5 TK TF TD RD RF RK ER T CT TWWD RTS0- CK C SC S0- TS R 3 RX K0- TS S 3 T D0 CK X D -RX 3 0 -T D5 X D D5 S DCR0 D R0 DT I0 R0 E T E XC T K ECXE -E R N ERRS -E XC T ERXE -EC XE K R O ET X0 -E L R - R M X0 ER XD D - X M C ETX 3 V D 3 F1 IO 00 A 6254CS–ATARM–08-Jan-10 D0 -A AD D3 TR IG AD VR EF VD DA NA G ND AN A D0-D15 A0/NBS0 A1/NBS2/NWR2 A2-A15, A18-A20 A16/BA0 A17/BA1 NCS0 NCS1/SDCS NRD NWR0/NWE NWR1/NBS1 NWR3/NBS3 SDCK, SDCKE RAS, CAS SDWE, SDA10 NANDOE, NANDWE A21/NANDALE A22/NANDCLE D16-D31 NWAIT A23-A24 NCS4/CFCS0 NCS5/CFCS1 A25/CFRNW CFCE1-CFCE2 NCS2, NCS6, NCS7 NCS3/NANDCS Figure 2-1. D D DDM P MASTER AT91SAM9XE128/256/512 Preliminary AT91SAM9XE128/256/512 Block Diagram 5 3. Signal Description Table 3-1 gives details on the signal name classified by peripheral. Table 3-1. Signal Name Signal Description List Function Type Active Level Reference Voltage Comments Power Supplies VDDIOM EBI I/O Lines Power Supply Power 1.65V to 1.95V or 3.0V to 3.6V VDDIOP0 Peripherals I/O Lines Power Supply Power 3.0V to 3.6V VDDIOP1 Peripherals I/O Lines Power Supply Power 1.65V to 3.6V VDDBU Backup I/O Lines Power Supply Power 1.65V to 1.95V VDDANA Analog Power Supply Power 3.0V to 3.6V VDDPLL PLL Power Supply Power 1.65V to 1.95V VDDCORE Core Chip and Embedded Memories Power Supply Power 1.65V to 1.95V GND Ground Ground GNDPLL PLL Ground Ground GNDANA Analog Ground Ground GNDBU Backup Ground Ground Clocks, Oscillators and PLLs XIN Main Oscillator Input Input XOUT Main Oscillator Output XIN32 Slow Clock Oscillator Input XOUT32 Slow Clock Oscillator Output OSCSEL Slow Clock Oscillator Selection Input PLLRCA PLL A Filter Input PCK0 - PCK1 Programmable Clock Output Output Input Output VDDBU Accepts between 0V and VDDBU. (2) Output Shutdown, Wakeup Logic SHDN Shutdown Control WKUP Wake-Up Input Output Low Input VDDBU Driven at 0V only. VDDBU Accepts between 0V and VDDBU. ICE and JTAG VDDIOP0 Pull-Up resistor (100 kΩ) Input VDDIOP0 No pull-up resistor, Schmitt trigger Input VDDIOP0 No pull-up resistor, Schmitt trigger Output VDDIOP0 Test Mode Select Input VDDIOP0 No pull-up resistor, Schmitt trigger JTAGSEL JTAG Selection Input VDDBU Pull-down resistor (15 kΩ). RTCK Return Test Clock Output VDDIOP0 NTRST Test Reset Signal Input TCK Test Clock TDI Test Data In TDO Test Data Out TMS 6 Low AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary Table 3-1. Signal Name Signal Description List (Continued) Function Type Active Level Reference Voltage Comments High VDDIOP0 Pull-down resistor (15 kΩ) Flash Memory ERASE Flash and NVM Configuration Bits Erase Command Input Reset/Test NRST Microcontroller Reset TST Test Mode Select I/O Low Input VDDIOP0 VDDBU Open-drain output, Pull-Up resistor (100 kΩ). Inserted in the Boundary Scan. Pull-down resistor (15 kΩ) Debug Unit - DBGU DRXD Debug Receive Data Input (2) DTXD Debug Transmit Data Output (2) Advanced Interrupt Controller - AIC IRQ0 - IRQ2 External Interrupt Inputs Input (2) FIQ Fast Interrupt Input Input (2) PIO Controller - PIOA - PIOB - PIOC PA0 - PA31 Parallel IO Controller A I/O VDDIOP0 Pulled-up input at reset (100kΩ)(1) PB0 - PB31 Parallel IO Controller B I/O VDDIOP0 Pulled-up input at reset (100kΩ)(1) PC0 - PC31 Parallel IO Controller C I/O (2) Pulled-up input at reset (100kΩ)(1) External Bus Interface - EBI D0 - D31 Data Bus A0 - A25 Address Bus NWAIT External Wait Signal I/O VDDIOM Pulled-up input at reset Output VDDIOM 0 at reset Input Low VDDIOM Static Memory Controller - SMC NCS0 - NCS7 Chip Select Lines Output Low VDDIOM NWR0 - NWR3 Write Signal Output Low VDDIOM NRD Read Signal Output Low VDDIOM NWE Write Enable Output Low VDDIOM NBS0 - NBS3 Byte Mask Signal Output Low VDDIOM 7 6254CS–ATARM–08-Jan-10 Table 3-1. Signal Name Signal Description List (Continued) Function Type Active Level Reference Voltage Comments CompactFlash Support CFCE1 - CFCE2 CompactFlash Chip Enable Output Low VDDIOM CFOE CompactFlash Output Enable Output Low VDDIOM CFWE CompactFlash Write Enable Output Low VDDIOM CFIOR CompactFlash IO Read Output Low VDDIOM CFIOW CompactFlash IO Write Output Low VDDIOM CFRNW CompactFlash Read Not Write Output CFCS0 - CFCS1 CompactFlash Chip Select Lines Output VDDIOM Low VDDIOM NAND Flash Support NANDCS NAND Flash Chip Select Output Low VDDIOM NANDOE NAND Flash Output Enable Output Low VDDIOM NANDWE NAND Flash Write Enable Output Low VDDIOM SDRAM Controller SDCK SDRAM Clock Output VDDIOM SDCKE SDRAM Clock Enable Output High VDDIOM SDCS SDRAM Controller Chip Select Output Low VDDIOM BA0 - BA1 Bank Select Output SDWE SDRAM Write Enable Output Low VDDIOM RAS - CAS Row and Column Signal Output Low VDDIOM SDA10 SDRAM Address 10 Line Output VDDIOM VDDIOM Multimedia Card Interface MCI MCCK Multimedia Card Clock Output VDDIOP0 MCCDA Multimedia Card Slot A Command I/O VDDIOP0 MCDA0 MCDA3 Multimedia Card Slot A Data I/O VDDIOP0 MCCDB Multimedia Card Slot B Command I/O VDDIOP0 MCDB0 MCDB3 Multimedia Card Slot B Data I/O VDDIOP0 Universal Synchronous Asynchronous Receiver Transmitter USARTx SCKx USARTx Serial Clock I/O (2) TXDx USARTx Transmit Data I/O (2) RXDx USARTx Receive Data Input (2) RTSx USARTx Request To Send Output (2) CTSx USARTx Clear To Send Input (2) DTR0 USART0 Data Terminal Ready Output (2) DSR0 USART0 Data Set Ready Input (2) DCD0 USART0 Data Carrier Detect Input (2) RI0 USART0 Ring Indicator Input (2) 8 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary Table 3-1. Signal Name Signal Description List (Continued) Function Type Active Level Reference Voltage Comments Synchronous Serial Controller - SSC TD SSC Transmit Data Output (2) RD SSC Receive Data Input (2) TK SSC Transmit Clock I/O (2) RK SSC Receive Clock I/O (2) TF SSC Transmit Frame Sync I/O (2) RF SSC Receive Frame Sync I/O (2) Timer/Counter - TCx Input (2) TC Channel x I/O Line A I/O (2) TC Channel x I/O Line B I/O (2) TCLKx TC Channel x External Clock Input TIOAx TIOBx Serial Peripheral Interface - SPIx_ SPIx_MISO Master In Slave Out I/O (2) SPIx_MOSI Master Out Slave In I/O (2) SPIx_SPCK SPI Serial Clock I/O (2) SPIx_NPCS0 SPI Peripheral Chip Select 0 I/O Low (2) SPIx_NPCS1SPIx_NPCS3 SPI Peripheral Chip Select Output Low (2) Two-Wire Interface TWDx Two-wire Serial Data I/O (2) TWCKx Two-wire Serial Clock I/O (2) USB Host Port HDPA USB Host Port A Data + Analog VDDIOP0 HDMA USB Host Port A Data - Analog VDDIOP0 HDPB USB Host Port B Data + Analog VDDIOP0 HDMB USB Host Port B Data + Analog VDDIOP0 USB Device Port DDM USB Device Port Data - Analog VDDIOP0 DDP USB Device Port Data + Analog VDDIOP0 9 6254CS–ATARM–08-Jan-10 Table 3-1. Signal Description List (Continued) Signal Name Function Type Active Level Reference Voltage Comments Ethernet 10/100 ETXCK Transmit Clock or Reference Clock Input VDDIOP0 MII only, REFCK in RMII ERXCK Receive Clock Input VDDIOP0 MII only ETXEN Transmit Enable Output VDDIOP0 ETX0-ETX3 Transmit Data Output VDDIOP0 ETX0-ETX1 only in RMII ETXER Transmit Coding Error Output VDDIOP0 MII only ERXDV Receive Data Valid Input VDDIOP0 RXDV in MII, CRSDV in RMII ERX0-ERX3 Receive Data Input VDDIOP0 ERX0-ERX1 only in RMII ERXER Receive Error Input VDDIOP0 ECRS Carrier Sense and Data Valid Input VDDIOP0 MII only ECOL Collision Detect Input VDDIOP0 MII only EMDC Management Data Clock Output VDDIOP0 EMDIO Management Data Input/Output I/O VDDIOP0 EF100 Force 100Mbit/sec. Output High VDDIOP0 Image Sensor Interface ISI_D0-ISI_D11 Image Sensor Data Input VDDIOP1 ISI_MCK Image sensor Reference clock output VDDIOP1 ISI_HSYNC Image Sensor Horizontal Synchro input VDDIOP1 ISI_VSYNC Image Sensor Vertical Synchro input VDDIOP1 ISI_PCK Image Sensor Data clock input VDDIOP1 Analog to Digital Converter AD0-AD3 Analog Inputs Analog VDDANA ADVREF Analog Positive Reference Analog VDDANA ADTRG ADC Trigger Input VDDANA Digital pulled-up inputs at reset Fast Flash Programming Interface PGMEN[3:0] Programming Enabling Input PGMNCMD Programming Command Input Low VDDIOP0 PGMRDY Programming Ready Output High VDDIOP0 PGMNOE Programming Read Input Low VDDIOP0 PGMNVALID Data Direction Output Low VDDIOP0 PGMM[3:0] Programming Mode Input VDDIOP0 PGMD[15:0] Programming Data I/O VDDIOP0 Notes: VDDIOP0 1. Programming of this pull-up resistor is performed independently for each I/O line through the PIO Controllers. After reset, all the I/O lines default as inputs with pull-up resistors enabled, except those which are multiplexed with the External Bus Interface signals that require to be enabled as Peripheral at reset. This is explicitly indicated in the column “Reset State” of the peripheral multiplexing tables. 2. Refer to PIO Multiplexing (see Section 10.3 “Peripheral Signals Multiplexing on I/O Lines”). 10 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 4. Package and Pinout The AT91SAM9XE128/256/512 is available in a 208-pin PQFP Green package (0.5mm pitch) or in a 217-ball LFBGA Green package (0.8 mm ball pitch). 4.1 208-pin PQFP Package Outline Figure 4-1 shows the orientation of the 208-pin PQFP package. A detailed mechanical description is given in the section “AT91SAM9XE Mechanical Characteristics” of the product datasheet. Figure 4-1. 208-pin PQFP Package Outline (Top View) 156 105 157 104 208 53 1 52 11 6254CS–ATARM–08-Jan-10 4.2 208-pin PQFP Package Pinout Table 4-1. Pinout for 208-pin PQFP Package Pin 1 Signal Name PA24 Pin 53 Signal Name GND Pin 105 Signal Name RAS Pin 157 Signal Name ADVREF 2 PA25 54 DDM 106 D0 158 PC0 3 PA26 55 DDP 107 D1 159 PC1 4 PA27 56 PC13 108 D2 160 VDDANA 5 VDDIOP0 57 PC11 109 D3 161 PB10 6 GND 58 PC10 110 D4 162 PB11 7 PA28 59 PC14 111 D5 163 PB20 8 PA29 60 PC9 112 D6 164 PB21 9 PB0 61 PC8 113 GND 165 PB22 10 PB1 62 PC4 114 VDDIOM 166 PB23 11 PB2 63 PC6 115 SDCK 167 PB24 12 PB3 64 PC7 116 SDWE 168 PB25 13 VDDIOP0 65 VDDIOM 117 SDCKE 169 VDDIOP1 14 GND 66 GND 118 D7 170 GND 15 PB4 67 PC5 119 D8 171 PB26 16 PB5 68 NCS0 120 D9 172 PB27 17 PB6 69 CFOE/NRD 121 D10 173 GND 18 PB7 70 CFWE/NWE/NWR0 122 D11 174 VDDCORE 19 PB8 71 NANDOE 123 D12 175 PB28 20 PB9 72 NANDWE 124 D13 176 PB29 21 PB14 73 A22 125 D14 177 PB30 22 PB15 74 A21 126 D15 178 PB31 23 PB16 75 A20 127 PC15 179 PA0 24 VDDIOP0 76 A19 128 PC16 180 PA1 25 GND 77 VDDCORE 129 PC17 181 PA2 26 PB17 78 GND 130 PC18 182 PA3 27 PB18 79 A18 131 PC19 183 PA4 28 PB19 80 BA1/A17 132 VDDIOM 184 PA5 29 TDO 81 BA0/A16 133 GND 185 PA6 30 TDI 82 A15 134 PC20 186 PA7 31 TMS 83 A14 135 PC21 187 VDDIOP0 32 VDDIOP0 84 A13 136 PC22 188 GND 33 GND 85 A12 137 PC23 189 PA8 34 TCK 86 A11 138 PC24 190 PA9 35 NTRST 87 A10 139 PC25 191 PA10 36 NRST 88 A9 140 PC26 192 PA11 37 RTCK 89 A8 141 PC27 193 PA12 38 VDDCORE 90 VDDIOM 142 PC28 194 PA13 39 GND 91 GND 143 PC29 195 PA14 40 ERASE 92 A7 144 PC30 196 PA15 41 OSCSEL 93 A6 145 PC31 197 PA16 42 TST 94 A5 146 GND 198 PA17 43 JTAGSEL 95 A4 147 VDDCORE 199 VDDIOP0 44 GNDBU 96 A3 148 VDDPLL 200 GND 45 XOUT32 97 A2 149 XIN 201 PA18 46 XIN32 98 NWR2/NBS2/A1 150 XOUT 202 PA19 47 VDDBU 99 NBS0/A0 151 GNDPLL 203 VDDCORE 48 WKUP 100 SDA10 152 NC 204 GND 12 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary Table 4-1. Pinout for 208-pin PQFP Package (Continued) Pin 49 Signal Name SHDN Pin 101 Signal Name CFIOW/NBS3/NWR3 Pin 153 Signal Name GNDPLL Pin 205 Signal Name PA20 50 HDMA 102 CFIOR/NBS1/NWR1 154 PLLRCA 206 PA21 51 HDPA 103 SDCS/NCS1 155 VDDPLL 207 PA22 52 VDDIOP0 104 CAS 156 GNDANA 208 PA23 4.3 217-ball LFBGA Package Outline Figure 4-2 shows the orientation of the 217-ball LFBGA package. A detailed mechanical description is given in the section “AT91SAM9XE Mechanical Characteristics” of the product datasheet. Figure 4-2. 217-ball LFBGA Package Outline (Top View) 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 A B C D E F G H J K L M N P R T U Ball A1 13 6254CS–ATARM–08-Jan-10 4.4 217-ball LFBGA Package Pinout Table 4-2. Pinout for 217-ball LFBGA Package Pin Signal Name Pin Signal Name Pin Signal Name Pin Signal Name A1 A2 A3 CFIOW/NBS3/NWR3 NBS0/A0 NWR2/NBS2/A1 D5 D6 D7 A5 GND A10 J14 J15 J16 TDO PB19 TDI P17 R1 R2 PB5 NC GNDANA A4 A6 D8 GND J17 PB16 R3 PC29 A5 A8 D9 VDDCORE K1 PC24 R4 VDDANA A6 A11 D10 GND K2 PC20 R5 PB12 A7 A13 D11 VDDIOM K3 D15 R6 PB23 A8 BA0/A16 D12 GND K4 PC21 R7 GND A9 A18 D13 DDM K8 GND R8 PB26 A10 A21 D14 HDPB K9 GND R9 PB28 A11 A22 D15 NC K10 GND R10 PA0 A12 CFWE/NWE/NWR0 D16 VDDBU K14 PB4 R11 PA4 A13 CFOE/NRD D17 XIN32 K15 PB17 R12 PA5 A14 NCS0 E1 D10 K16 GND R13 PA10 A15 PC5 E2 D5 K17 PB15 R14 PA21 A16 PC6 E3 D3 L1 GND R15 PA23 A17 PC4 E4 D4 L2 PC26 R16 PA24 B1 SDCK E14 HDPA L3 PC25 R17 PA29 B2 CFIOR/NBS1/NWR1 E15 HDMA L4 VDDIOP0 T1 PLLRCA B3 SDCS/NCS1 E16 GNDBU L14 PA28 T2 GNDPLL B4 SDA10 E17 XOUT32 L15 PB9 T3 PC0 B5 A3 F1 D13 L16 PB8 T4 PC1 B6 A7 F2 SDWE L17 PB14 T5 PB10 B7 A12 F3 D6 M1 VDDCORE T6 PB22 B8 A15 F4 GND M2 PC31 T7 GND B9 A20 F14 OSCSEL M3 GND T8 PB29 B10 NANDWE F15 ERASE M4 PC22 T9 PA2 B11 PC7 F16 JTAGSEL M14 PB1 T10 PA6 PA8 B12 PC10 F17 TST M15 PB2 T11 B13 PC13 G1 PC15 M16 PB3 T12 PA11 B14 PC11 G2 D7 M17 PB7 T13 VDDCORE B15 PC14 G3 SDCKE N1 XIN T14 PA20 B16 PC8 G4 VDDIOM N2 VDDPLL T15 GND B17 WKUP G14 GND N3 PC23 T16 PA22 C1 D8 G15 NRST N4 PC27 T17 PA27 C2 D1 G16 RTCK N14 PA31 U1 GNDPLL C3 CAS G17 TMS N15 PA30 U2 ADVREF C4 A2 H1 PC18 N16 PB0 U3 PC2 C5 A4 H2 D14 N17 PB6 U4 PC3 C6 A9 H3 D12 P1 XOUT U5 PB20 C7 A14 H4 D11 P2 VDDPLL U6 PB21 C8 BA1/A17 H8 GND P3 PC30 U7 PB25 C9 A19 H9 GND P4 PC28 U8 PB27 C10 NANDOE H10 GND P5 PB11 U9 PA12 C11 PC9 H14 VDDCORE P6 PB13 U10 PA13 C12 PC12 H15 TCK P7 PB24 U11 PA14 C13 DDP H16 NTRST P8 VDDIOP1 U12 PA15 C14 HDMB H17 PB18 P9 PB30 U13 PA19 C15 NC J1 PC19 P10 PB31 U14 PA17 C16 VDDIOP0 J2 PC17 P11 PA1 U15 PA16 14 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary Table 4-2. Pin Pinout for 217-ball LFBGA Package (Continued) Signal Name Pin Signal Name Pin Signal Name Pin Signal Name C17 SHDN J3 VDDIOM P12 PA3 U16 PA18 D1 D9 J4 PC16 P13 PA7 U17 VDDIOP0 PA9 D2 D2 J8 GND P14 D3 RAS J9 GND P15 PA26 D4 D0 J10 GND P16 PA25 5. Power Considerations 5.1 Power Supplies The AT91SAM9XE128/256/512 has several types of power supply pins: • VDDCORE pins: Power the core, including the processor, the embedded memories and the peripherals; voltage ranges from 1.65V and 1.95V, 1.8V nominal. • VDDIOM pins: Power the External Bus Interface I/O lines; voltage ranges between 1.65V and 1.95V (1.8V typical) or between 3.0V and 3.6V (3.3V nominal). The expected voltage range is selectable by software. • VDDIOP0 pins: Power the Peripheral I/O lines and the USB transceivers; voltage ranges from 3.0V and 3.6V, 3V or 3.3V nominal. • VDDIOP1 pin: Powers the Peripherals I/O lines involving the Image Sensor Interface; voltage ranges from 1.65V and 3.6V, 1.8V, 2.5V, 3V or 3.3V nominal. • VDDBU pin: Powers the Slow Clock oscillator and a part of the System Controller; voltage ranges from 1.65V to 1.95V, 1.8V nominal. • VDDPLL pins: Power the PLL cells and the main oscillator; voltage ranges from 1.65V and 1.95V, 1.8V nominal. • VDDANA pin: Powers the Analog to Digital Converter; voltage ranges from 3.0V and 3.6V, 3.3V nominal. The power supplies VDDIOM, VDDIOP0 and VDDIOP1 are identified in the pinout table and their associated I/O lines in the multiplexing tables. These supplies enable the user to power the device differently for interfacing with memories and for interfacing with peripherals. Ground pins GND are common to VDDCORE, VDDIOM, VDDIOP0 and VDDIOP1 pins power supplies. Separated ground pins are provided for VDDBU, VDDPLL and VDDANA. These ground pins are respectively GNDBU, GNDPLL and GNDANA. 6. I/O Line Considerations 6.1 ERASE Pin The ERASE pin is used to re-initialize the Flash content and the NVM bits. It integrates a permanent pull-down resistor of about 15 kΩ, so that it can be left unconnected for normal operations. The ERASE pin is powered by VDDIOP0 rail. This pin is debounced on the RC oscillator or 32,768 Hz low-power oscillator to improve the glitch tolerance. Minimum debouncing time is 200 ms. 15 6254CS–ATARM–08-Jan-10 6.2 I/O Line Drive Levels The PIO lines PA0 to PA31 and PB0 to PB31 and PC0 to PC3 are high-drive current capable. Each of these I/O lines can drive up to 16 mA permanently with a total of 350 mA on all I/O lines. Refer to the “DC Characteristics” section of the product datasheet. 6.3 Shutdown Logic Pins The SHDN pin is a tri-state output only pin, which is driven by the Shutdown Controller. There is no internal pull-up. An external pull-up to VDDBU is needed and its value must be higher than 1 MΩ. The resisitor value is calculated according to the regulator enable implementation and the SHDN level. The WKUP pin is an input-only. It can accept voltages only between 0V and VDDBU. 7. Processor and Architecture 7.1 ARM926EJ-S Processor • RISC Processor Based on ARM v5TEJ Architecture with Jazelle technology for Java acceleration • Two Instruction Sets – ARM High-performance 32-bit Instruction Set – Thumb High Code Density 16-bit Instruction Set • DSP Instruction Extensions • 5-Stage Pipeline Architecture: – Instruction Fetch (F) – Instruction Decode (D) – Execute (E) – Data Memory (M) – Register Write (W) • 8 Kbytes Data Cache, 16 Kbytes Instruction Cache – Virtually-addressed 4-way Associative Cache – Eight words per line – Write-through and Write-back Operation – Pseudo-random or Round-robin Replacement • Write Buffer – Main Write Buffer with 16-word Data Buffer and 4-address Buffer – DCache Write-back Buffer with 8-word Entries and a Single Address Entry – Software Control Drain • Standard ARM v4 and v5 Memory Management Unit (MMU) – Access Permission for Sections – Access Permission for large pages and small pages can be specified separately for each quarter of the page – 16 embedded domains • Bus Interface Unit (BIU) 16 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary – Arbitrates and Schedules AHB Requests – Separate Masters for both instruction and data access providing complete Matrix system flexibility – Separate Address and Data Buses for both the 32-bit instruction interface and the 32-bit data interface – On Address and Data Buses, data can be 8-bit (Bytes), 16-bit (Half-words) or 32-bit (Words) 7.2 Bus Matrix • 6-layer Matrix, handling requests from 6 masters • Programmable Arbitration strategy – Fixed-priority Arbitration – Round-Robin Arbitration, either with no default master, last accessed default master or fixed default master • Burst Management – Breaking with Slot Cycle Limit Support – Undefined Burst Length Support • One Address Decoder provided per Master – Three different slaves may be assigned to each decoded memory area: one for internal ROM boot, one for internal flash boot, one after remap • Boot Mode Select – Non-volatile Boot Memory can be internal ROM or internal Flash – Selection is made by General purpose NVM bit sampled at reset • Remap Command – Allows Remapping of an Internal SRAM in Place of the Boot Non-Volatile Memory (ROM or Flash) – Allows Handling of Dynamic Exception Vectors 7.2.1 Matrix Masters The Bus Matrix of the AT91SAM9XE128/256/512 manages six Masters, thus each master can perform an access concurrently with others, depending on whether the slave it accesses is available. Each Master has its own decoder, which can be defined specifically for each master. In order to simplify the addressing, all the masters have the same decodings. Table 7-1. List of Bus Matrix Masters Master 0 ARM926™ Instruction Master 1 ARM926 Data Master 2 Peripheral DMA Controller Master 3 USB Host Controller Master 4 Image Sensor Controller Master 5 Ethernet MAC 17 6254CS–ATARM–08-Jan-10 7.2.2 Matrix Slaves Each Slave has its own arbiter, thus allowing a different arbitration per Slave to be programmed. Table 7-2. List of Bus Matrix Slaves Slave 0 Internal SRAM Internal ROM Slave 1 USB Host User Interface 7.2.3 Slave 2 External Bus Interface Slave 3 Internal Flash Slave 4 Internal Peripherals Slave 5 Reserved Masters to Slaves Access All the Masters can normally access all the Slaves. However, some paths do not make sense, such as allowing access from the Ethernet MAC to the internal peripherals. Thus, these paths are forbidden or simply not wired, and shown as “–” in the following table. Table 7-3. Masters to Slaves Access Master 0 and 1 2 3 4 5 ARM926 Instruction and Data Periphera DMA Controller ISI Controller Ethernet MAC USB Host Controller Internal SRAM X X X X X Internal ROM X X – – – UHP User Interface X – – – – 2 External Bus Interface X – – X 3 Internal Flash X X X X X 4 Internal Peripherals X X – – – Reserved – – – – – Slave 0 1 7.3 Peripheral DMA Controller • Acting as one Matrix Master • Allows data transfers from/to peripheral to/from any memory space without any intervention of the processor. • Next Pointer Support, forbids strong real-time constraints on buffer management. • Twenty-four channels – Two for each USART – Two for the Debug Unit – Two for each Serial Synchronous Controller – Two for each Serial Peripheral Interface – Two for the Two Wire Interface – One for Multimedia Card Interface – One for Analog To Digital Converter 18 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary The Peripheral DMA Controller handles transfer requests from the channel according to the following priorities (Low to High priorities): – TWI0 Transmit Channel – TWI1 Transmit Channel – DBGU Transmit Channel – USART4 Transmit Channel – USART3 Transmit Channel – USART2 Transmit Channel – USART1 Transmit Channel – USART0 Transmit Channel – SPI1 Transmit Channel – SPI0 Transmit Channel – SSC Transmit Channel – TWI0 Receive Channel – TWI1 Receive Channel – DBGU Receive Channel – USART4 Receive Channel – USART3 Receive Channel – USART2 Receive Channel – USART1 Receive Channel – USART0 Receive Channel – ADC Receive Channel – SPI1 Receive Channel – SPI0 Receive Channel – SSC Receive Channel – MCI Transmit/Receive Channel 7.4 Debug and Test Features • ARM926 Real-time In-circuit Emulator – Two real-time Watchpoint Units – Two Independent Registers: Debug Control Register and Debug Status Register – Test Access Port Accessible through JTAG Protocol – Debug Communications Channel • Debug Unit – Two-pin UART – Debug Communication Channel Interrupt Handling – Chip ID Register • IEEE1149.1 JTAG Boundary-scan on All Digital Pins 19 6254CS–ATARM–08-Jan-10 8. Memories Figure 8-1. AT91SAM9XE128/256/512 Memory Mapping Address Memory Space Internal Memory Mapping 0x0000 0000 Notes : (1) Can be ROM or Flash depending on GPNVM[3] 0x0000 0000 Boot Memory (1) Internal Memories 256M Bytes 0x10 0000 ROM 0x0FFF FFFF EBI Chip Select 0 Reserved 256M Bytes 0x20 0000 Flash 128, 256 or 512K Bytes 0x28 0000 0x1FFF FFFF 0x2000 0000 0x2FFF FFFF 32K Bytes 0x10 8000 0x1000 0000 Reserved EBI Chip Select 1/ SDRAMC 256M Bytes 0x30 0000 SRAM 32K Bytes 0x30 8000 Reserved 0x3000 0000 0x50 0000 EBI Chip Select 2 256M Bytes 0x50 4000 EBI Chip Select 3/ NANDFlash 256M Bytes 0x0FFF FFFF EBI Chip Select 4/ Compact Flash Slot 0 256M Bytes EBI Chip Select 5/ Compact Flash Slot 1 256M Bytes UHP 16K Bytes 0x3FFF FFFF 0x4000 0000 Reserved 0x4FFF FFFF 0x5000 0000 0x5FFF FFFF 0x6000 0000 0x6FFF FFFF 0x7000 0000 Peripheral Mapping 0xF000 0000 System Controller Mapping Reserved 0xFFFA 0000 EBI Chip Select 6 256M Bytes 16K Bytes UDP 16K Bytes MCI 16K Bytes TWI0 16K Bytes 0xFFFF C000 Reserved 0xFFFA 4000 0x7FFF FFFF 0x8000 0000 TCO, TC1, TC2 0xFFFF E800 0xFFFA 8000 EBI Chip Select 7 256M Bytes 0xFFFA C000 0x8FFF FFFF 0x9000 0000 ECC 512 Bytes SDRAMC 512 Bytes SMC 512 Bytes 0xFFFF EA00 0xFFFF EC00 0xFFFB 0000 USART0 16K Bytes 0xFFFB 4000 0xFFFF EE00 USART1 16K Bytes 0xFFFB 8000 USART2 16K Bytes SSC 16K Bytes ISI 16K Bytes EMAC 16K Bytes MATRIX 0xFFFF EF10 0xFFFF F000 0xFFFB C000 512 Bytes CCFG 512 Bytes AIC 0xFFFF F200 0xFFFC 0000 0xFFFC 4000 1,518M Bytes SPI0 16K Bytes 0xFFFC C000 SPI1 16K Bytes USART3 16K Bytes USART4 TWI1 16K Bytes 0xFFFF FC00 16K Bytes 0xFFFF FD00 TC3, TC4, TC5 16K Bytes ADC 16K Bytes 0xFFFE 0000 0xFFFF FD20 0xFFFF FD30 0xFFFF FD50 Reserved 20 512 bytes EEFC 512 bytes PMC 256 Bytes RSTC 16 Bytes SHDC 16 Bytes RTTC 16 Bytes PITC 16 Bytes WDTC 16 Bytes 0xFFFF FD40 0xFFFE 4000 256M Bytes PIOC 0xFFFF FD10 0xFFFD C000 Internal Peripherals 512 bytes 0xFFFF FA00 0xFFFD 8000 0xFFFF FFFF 512 Bytes PIOB 0xFFFD 4000 0xEFFF FFFF PIOA 0xFFFF F800 0xFFFD 0000 0xF000 0000 512 Bytes 0xFFFF F600 0xFFFC 8000 Undefined (Abort) DBGU 0xFFFF F400 0xFFFF C000 Reserved 0xFFFF FD60 SYSC 16K Bytes 0xFFFF FFFF 0xFFFF FD70 0xFFFF FFFF GPBR 16 Bytes Reserved AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary A first level of address decoding is performed by the Bus Matrix, i.e., the implementation of the Advanced High performance Bus (AHB) for its Master and Slave interfaces with additional features. Decoding breaks up the 4 Gbytes of address space into 16 banks of 256 Mbytes. The banks 1 to 7 are directed to the EBI that associates these banks to the external chip selects EBI_NCS0 to EBI_NCS7. Bank 0 is reserved for the addressing of the internal memories, and a second level of decoding provides 1 Mbyte of internal memory area. Bank 15 is reserved for the peripherals and provides access to the Advanced Peripheral Bus (APB). Other areas are unused and performing an access within them provides an abort to the master requesting such an access. Each Master has its own bus and its own decoder, thus allowing a different memory mapping per Master. However, in order to simplify the mappings, all the masters have a similar address decoding. Regarding Master 0 and Master 1 (ARM926 Instruction and Data), three different Slaves are assigned to the memory space decoded at address 0x0: one for internal boot, one for external boot, one after remap, refer to Table 8-3, “Internal Memory Mapping,” on page 25 for details. A complete memory map is presented in Figure 8-1 on page 20. 8.1 8.1.1 Embedded Memories AT91SAM9XE128 • 32 Kbytes ROM – Single Cycle Access at full matrix speed • 16 Kbytes Fast SRAM – Single Cycle Access at full matrix speed • 128 Kbytes Embedded Flash 8.1.2 AT91SAM9XE256 • 32 Kbytes ROM – Single Cycle Access at full matrix speed • 32 Kbytes Fast SRAM – Single Cycle Access at full matrix speed • 256 Kbytes Embedded Flash 8.1.3 AT91SAM9XE512 • 32 Kbytes ROM – Single Cycle Access at full matrix speed • 32 Kbytes Fast SRAM – Single Cycle Access at full matrix speed • 512 Kbytes Embedded Flash 8.1.4 ROM Topology The embedded ROM contains the Fast Flash Programming and the SAM-BA boot programs. Each of these two programs is stored on 16-Kbyte Boundary of FFPI and the program executed 21 6254CS–ATARM–08-Jan-10 at address zero depends on the combination of the TST pin and PA0 to PA3 pins. Figure 8-2 shows the contents of the ROM and the program available at address zero. Figure 8-2. ROM Boot Memory Map 0x0000 0000 0x0000 0000 0x0000 0000 SAM-BA Program SAM-BA Program FFPI Program FFPI Program 0x0000 7FFF 0x0000 3FFF ROM 8.1.4.1 0x0000 3FFF TST=0 TST=1 PA0=1 PA1=1 PA2=0 PA3=0 Fast Flash Programming Interface The Fast Flash Programming Interface programs the device through a serial JTAG interface or a multiplexed fully-handshaked parallel port. It allows gang-programming with market-standard industrial programmers. The FFPI supports read, page program, page erase, full erase, lock, unlock and protect commands. The Fast Flash Programming Interface is enabled and the Fast Programming Mode is entered when the TST pin and the PA0 and PA1 pins are all tied high, while PA2 and PA3 are tied low. Table 8-1. 8.1.4.2 22 Signal Description Signal Name PIO Type Active Level Comments PGMEN0 PA0 Input High Must be connected to VDDIO PGMEN1 PA1 Input High Must be connected to VDDIO PGMEN2 PA2 Input Low Must be connected to GND PGMEN3 PA3 Input Low Must be connected to GND PGMNCMD PA4 Input Low Pulled-up input at reset PGMRDY PA5 Output High Pulled-up input at reset PGMNOE PA6 Input Low Pulled-up input at reset PGMNVALID PA7 Output Low Pulled-up input at reset PGMM[3:0] PA8..PA10 Input Pulled-up input at reset PGMD[15:0] PA12..PA27 Input/Output Pulled-up input at reset SAM-BA® Boot Assistant The SAM-BA Boot Assistant is a default Boot Program that provides an easy way to program in situ the on-chip Flash memory. AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary The SAM-BA Boot Assistant supports serial communication through the DBGU or through the USB Device Port. • Communication through the DBGU supports a wide range of crystals from 3 to 20 MHz via software auto-detection. • Communication through the USB Device Port is depends on crystal selected: – limited to an 18,432 Hz crystal if the internal RC oscillator is selected – supports a wide range of crystals from 3 to 20 MHz if the 32,768 Hz crystal is selected The SAM-BA Boot provides an interface with SAM-BA Graphic User Interface (GUI). 8.1.5 Embedded Flash The Flash of the AT91SAM9XE128/256/512 is organized in 256/512/1024 pages of 512 bytes directly connected to the 32-bit internal bus. Each page contains 128 words. The Flash contains a 512-byte write buffer allowing the programming of a page. This buffer is write-only as 128 32-bit words, and accessible all along the 1-Mbyte address space, so that each word can be written at its final address. The Flash benefits from the integration of a power reset cell and from a brownout detector to prevent code corruption during power supply changes, even in the worst conditions. 8.1.5.1 Enhanced Embedded Flash Controller The Enhanced Embedded Flash Controller (EEFC) is continuously clocked. The Enhanced Embedded Flash Controller (EEFC) is a slave for the bus matrix and is configurable through its User Interface on the APB bus. It ensures the interface of the Flash block with the 32-bit internal bus. Its 128-bit wide memory interface increases performance, four 32-bit data are read during each access, this multiply the throughput by 4 in case of consecutive data. It also manages the programming, erasing, locking and unlocking sequences of the Flash using a full set of commands. One of the commands returns the embedded Flash descriptor definition that informs the system about the Flash organization, thus making the software generic programming of the access parameters of the Flash (number of wait states, timings, etc.) 8.1.5.2 Lock Regions The memory plane of 128, 256 or 512 Kbytes is organized in 8, 16 or 32 locked regions of 32 pages each. Each lock region can be locked independently, so that the software protects the first memory plane against erroneous programming: If a locked-regions erase or program command occurs, the command is aborted and the EEFC could trigger an interrupt. The Lock bits are software programmable through the EEFC User Interface. The command “Set Lock Bit” enables the protection. The command “Clear Lock Bit” unlocks the lock region. Asserting the ERASE pin clears the lock bits, thus unlocking the entire Flash. 23 6254CS–ATARM–08-Jan-10 Figure 8-3. Flash First Memory Plane Mapping 0x0020 0000 Locked Region 0 Page 0 Locked Regions Area 128, 256 or 512 Kbytes 256, 512 or 1024 Pages Page 31 Locked Region 7, 15 or 31 0x0021 FFFF or 0x0023 FFFF or 0x0027 FFFF 8.1.5.3 512 bytes 16 Kbytes 32 bits wide GPNVM Bits The AT91SAM9XE128/256/512 features four GPNVM bits that can be cleared or set respectively through the commands “Clear GPNVM Bit” and “Set GPNVM Bit” of the EEFC User Interface. Table 8-2. GPNVMBit[#] 8.1.5.4 General-purpose Non volatile Memory Bits Function 0 Security Bit 1 Brownout Detector Enable 2 Brownout Detector Reset Enable 3 Boot Mode Select (BMS) Security Bit The AT91SAM9XE128/256/512 features a security bit, based on a specific GPNVM bit, GPNVMBit[0]. When the security is enabled, access to the Flash, either through the ICE interface or through the Fast Flash Programming Interface, is forbidden. This ensures the confidentiality of the code programmed in the Flash. Disabling the security bit can only be achieved by asserting the ERASE pin at 1, and after a full Flash erase is performed. When the security bit is deactivated, all accesses to the Flash are permitted. As the ERASE pin integrates a permanent pull-down, it can be left unconnected during normal operation. 24 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 8.1.5.5 Non-volatile Brownout Detector Control Two GPNVM bits are used for controlling the brownout detector (BOD), so that even after a power loss, the brownout detector operations remain in their state. • GPNVMBit[1] is used as a brownout detector enable bit. Setting GPNVMBit[1] enables the BOD, clearing it disables the BOD. Asserting ERASE clears GPNVMBit[1] and thus disables the brownout detector by default. • GPNVMBit[2] is used as a brownout reset enable signal for the reset controller. Setting GPNVMBit[2] enables the brownout reset when a brownout is detected, clearing GPNVMBit[2] disables the brownout reset. Asserting ERASE disables the brownout reset by default. 8.1.6 Boot Strategies Table 8-3 summarizes the Internal Memory Mapping for each Master, depending on the Remap status and the GPNVMBit[3] state at reset. Table 8-3. Internal Memory Mapping REMAP = 0 REMAP = 1 Address 0x0000 0000 GPNVMBit[3] clear GPNVMBit[3] set ROM Flash SRAM The system always boots at address 0x0. To ensure a maximum number of possibilities for boot, the memory layout can be configured with two parameters. REMAP allows the user to lay out the first internal SRAM bank to 0x0 to ease development. This is done by software once the system has booted. Refer to the section “AT91SAM9XE Bus Matrix” in the product datasheet for more details. When REMAP = 0, a non volatile bit stored in Flash memory (GPNVMBit[3]) allows the user to lay out to 0x0, at his convenience, the ROM or the Flash. Refer to the section “Enhanced Embedded Flash Controller (EEFC)” in the product datasheet for more details. Note: Memory blocks not affected by these parameters can always be seen at their specified base addresses. See the complete memory map presented in Figure 8-1 on page 20. The AT91SAM9XE Matrix manages a boot memory that depends on the value of GPNVMBit[3] at reset. The internal memory area mapped between address 0x0 and 0x0FFF FFFF is reserved for this purpose. If GPNVMBit[3] is set, the boot memory is the internal Flash memory If GPNVMBit[3] is clear (Flash reset State), the boot memory is the embedded ROM. After a Flash erase, the boot memory is the internal ROM. 8.1.6.1 GPNVMBit[3] = 0, Boot on Embedded ROM The system boots using the Boot Program. • Boot on slow clock (On-chip RC oscillator or 32,768 Hz low-power oscillator) • Auto baudrate detection • SAM-BA Boot in case no valid program is detected in external NVM, supporting – Serial communication on a DBGU – USB Device Port 25 6254CS–ATARM–08-Jan-10 8.1.6.2 GPNVMBit[3] = 1, Boot on Internal Flash • Boot on slow clock (On-chip RC oscillator or 32,768 Hz low-power oscillator) The customer-programmed software must perform a complete configuration. To speed up the boot sequence when booting at 32 kHz, the user must take the following steps: 1. Program the PMC (main oscillator enable or bypass mode) 2. Program and start the PLL 3. Switch the main clock to the new value. 8.2 External Memories The external memories are accessed through the External Bus Interface. Each Chip Select line has a 256-Mbyte memory area assigned. Refer to the memory map in Figure 8-1 on page 20. 8.2.1 External Bus Interface • Integrates three External Memory Controllers: – Static Memory Controller – SDRAM Controller – ECC Controller • Additional logic for NANDFlash • Full 32-bit External Data Bus • Up to 26-bit Address Bus (up to 64 Mbytes linear) • Up to 8 chip selects, Configurable Assignment: – Static Memory Controller on NCS0 – SDRAM Controller or Static Memory Controller on NCS1 – Static Memory Controller on NCS2 – Static Memory Controller on NCS3, Optional NAND Flash support – Static Memory Controller on NCS4 - NCS5, Optional CompactFlash support – Static Memory Controller on NCS6-NCS7 8.2.2 Static Memory Controller • 8-, 16- or 32-bit Data Bus • Multiple Access Modes supported – Byte Write or Byte Select Lines – Asynchronous read in Page Mode supported (4- up to 32-byte page size) • Multiple device adaptability – Compliant with LCD Module – Control signals programmable setup, pulse and hold time for each Memory Bank • Multiple Wait State Management – Programmable Wait State Generation – External Wait Request – Programmable Data Float Time • Slow Clock mode supported 26 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 8.2.3 SDRAM Controller • Supported devices: – Standard and Low Power SDRAM (Mobile SDRAM) • Numerous configurations supported – 2K, 4K, 8K Row Address Memory Parts – SDRAM with two or four Internal Banks – SDRAM with 16- or 32-bit Data Path • Programming facilities – Word, half-word, byte access – Automatic page break when Memory Boundary has been reached – Multibank Ping-pong Access – Timing parameters specified by software – Automatic refresh operation, refresh rate is programmable • Energy-saving capabilities – Self-refresh, power down and deep power down modes supported • Error detection – Refresh Error Interrupt • SDRAM Power-up Initialization by software • CAS Latency of 1, 2 and 3 supported • Auto Precharge Command not used 8.2.4 Error Corrected Code Controller • Hardware error corrected code generation – Detection and correction by software • Supports NAND Flash and SmartMedia devices with 8- or 16-bit data path • Supports NAND Flash and SmartMedia with page sizes of 528,1056, 2112 and 4224 bytes specified by software • Supports 1 bit correction for a page of 512, 1024, 2112 and 4096 bytes with 8- or 16-bit data path • Supports 1 bit correction per 512 bytes of data for a page size of 512, 2048 and 4096 bytes with 8-bit data path • Supports 1 bit correction per 256 bytes of data for a page size of 512, 2048 and 4096 bytes with 8-bit data path 8.2.5 I/O Drive Selection The purpose of this control is to adapt the signal to the frequency. Two bits enable the user to select High or Low Drive for memory data/addresses/control signals. Setting the EBI_DRIVE field [17:16] in the EBI Chip Select Assignement Register (EBI_CSA) located in the Chip Select Interface of the Bus Matrix, enables control of the EBI. 27 6254CS–ATARM–08-Jan-10 9. System Controller The System Controller is a set of peripherals that allows handling of key elements of the system, such as power, resets, clocks, time, interrupts, watchdog, etc. The System Controller User Interface also embeds the registers that configure the Matrix and a set of registers for the chip configuration. The chip configuration registers configure the EBI chip select assignment and voltage range for external memories. The System Controller’s peripherals are all mapped within the highest 16 Kbytes of address space, between addresses 0xFFFF E800 and 0xFFFF FFFF. However, all the registers of System Controller are mapped on the top of the address space. All the registers of the System Controller can be addressed from a single pointer by using the standard ARM instruction set, as the Load/Store instruction have an indexing mode of ±4 Kbytes. Figure 9-1 on page 29 shows the System Controller block diagram. Figure 8-1 on page 20 shows the mapping of the User Interfaces of the System Controller peripherals. 28 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 9.1 System Controller Block Diagram Figure 9-1. AT91SAM9XE128/256/512 System Controller Block Diagram System Controller VDDCORE Powered irq0-irq2 fiq periph_irq[2..24] efc2_irq pit_irq rtt_irq wdt_irq dbgu_irq pmc_irq rstc_irq ntrst PCK debug MCK periph_nreset dbgu_rxd Debug Unit MCK debug periph_nreset Periodic Interval Timer pit_irq Watchdog Timer wdt_irq gpnvm[2] POR dbgu_txd jtag_nreset MCK periph_nreset Reset Controller periph_nreset proc_nreset backup_nreset security_bit(gpnvm0) flash_poe flash_poe flash_wrdis VDDBU Powered SLCK SLCK backup_nreset Real-Time Timer rtt_irq SLCK XIN32 XOUT32 gpnvm[1..3] backup_nreset periph_clk[20] Shutdown Controller periph_nreset rtt0_alarm USB Host Port periph_irq[20] SLOW CLOCK OSC 4 General-Purpose Backup Registers SLCK XIN cal UHPCK WKUP OSCSEL Embedded Flash rtt_alarm SHDN RC OSC Bus Matrix rstc_irq NRST VDDBU POR Boundary Scan TAP Controller gpnvm[3] bod_rst_en BOD por_ntrst jtag_nreset dbgu_irq wdt_fault WDRPROC flash_wrdis VDDBU ARM926EJ-S proc_nreset cal gpnvm[1] VDDCORE por_ntrst int SLCK debug idle proc_nreset VDDCORE nirq nfiq Advanced Interrupt Controller UDPCK int MAIN OSC MAINCK XOUT PLLRCA PLLA PLLACK PLLB Power Management Controller periph_clk[2..27] pck[0-1] periph_clk[10] PCK UDPCK periph_nreset USB Device Port periph_irq[10] UHPCK MCK PLLBCK pmc_irq periph_nreset idle periph_clk[6..24] periph_nreset periph_nreset periph_clk[2..4] dbgu_rxd PA0-PA31 PB0-PB31 PC0-PC31 PIO Controllers periph_irq[2..4] irq0-irq2 fiq dbgu_txd Embedded Peripherals periph_irq[6..24] in out enable 29 6254CS–ATARM–08-Jan-10 9.2 Reset Controller • Based on two Power-on reset cells – One on VDDBU and one on VDDCORE • Status of the last reset – Either general reset (VDDBU rising), wake-up reset (VDDCORE rising), software reset, user reset or watchdog reset • Controls the internal resets and the NRST pin output – Allows shaping a reset signal for the external devices – At reset the NRST pin is an output 9.3 Brownout Detector and Power-on Reset The AT91SAM9XE128/256/512 embeds one brownout detection circuit and power-on reset cells. The power-on reset are supplied with and monitor VDDCORE and VDDBU. Signals (flash_poe and flash_wrdis) are provided to the Flash to prevent any code corruption during power-up or power-down sequences or if brownouts occur on the VDDCORE power supply. The power-on reset cell has a limited-accuracy threshold at around 1.5V. Its output remains low during power-up until VDDCORE goes over this voltage level. This signal goes to the reset controller and allows a full re-initialization of the device. The brownout detector monitors the VDDCORE level during operation by comparing it to a fixed trigger level. It secures system operations in the most difficult environments and prevents code corruption in case of brownout on the VDDCORE. When the brownout detector is enabled and VDDCORE decreases to a value below the trigger level (Vbot-), the brownout output is immediately activated. For more details on Vbot, see the table “Brownout Detector Characteristics” in the section “AT91SAM9XE128/256/512 Electrical Characteristics” in the full datasheet. When VDDCORE increases above the trigger level (Vbot+, defined as Vbot + Vhyst), the reset is released. The brownout detector only detects a drop if the voltage on VDDCORE stays below the threshold voltage for longer than about 1µs. The VDDCORE threshold voltage has a hysteresis of about 50 mV typical, to ensure spike free brownout detection. The typical value of the brownout detector threshold is 1.55V with an accuracy of ± 2% and is factory calibrated. The brownout detector is low-power, as it consumes less than 12 µA static current. However, it can be deactivated to save its static current. In this case, it consumes less than 1 µA. The deactivation is configured through the GPNVMBit[1] of the Flash. Additional information can be found in the “Electrical Characteristics” section of the product datasheet. 9.4 Shutdown Controller • Shutdown and Wake-Up logic – Software programmable assertion of the SHDN pin – Deassertion Programmable on a WKUP pin level change or on alarm 30 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 9.5 Clock Generator • Embeds a low power 32,768 Hz slow clock oscillator and a low-power RC oscillator selectable with OSCSEL signal – Provides the permanent slow clock SLCK to the system • Embeds the main oscillator – Oscillator bypass feature – Supports 3 to 20 MHz crystals • Embeds 2 PLLs – PLL A outputs 80 to 240 MHz clock – PLL B outputs 70 MHz to 130 MHz clock – Both integrate an input divider to increase output accuracy – PLLB embeds its own filter 9.6 Power Management Controller • Provides: – the Processor Clock PCK – the Master Clock MCK, in particular to the Matrix and the memory interfaces – the USB Device Clock UDPCK – independent peripheral clocks, typically at the frequency of MCK – 2 programmable clock outputs: PCK0, PCK1 • Five flexible operating modes: – Normal Mode, processor and peripherals running at a programmable frequency – Idle Mode, processor stopped waiting for an interrupt – Slow Clock Mode, processor and peripherals running at low frequency – Standby Mode, mix of Idle and Backup Mode, peripheral running at low frequency, processor stopped waiting for an interrupt – Backup Mode, Main Power Supplies off, VDDBU powered by a battery 9.7 Periodic Interval Timer • Includes a 20-bit Periodic Counter, with less than 1 µs accuracy • Includes a 12-bit Interval Overlay Counter • Real Time OS or Linux®/WindowsCE® compliant tick generator 9.8 Watchdog Timer • 16-bit key-protected only-once-Programmable Counter • Windowed, prevents the processor to be in a dead-lock on the watchdog access 9.9 Real-time Timer • Real-time Timer with 32-bit free-running back-up counter • Integrates a 16-bit programmable prescaler running on slow clock • Alarm Register capable to generate a wake-up of the system through the Shutdown Controller 31 6254CS–ATARM–08-Jan-10 9.10 General-purpose Back-up Registers • Four 32-bit backup general-purpose registers 9.11 Advanced Interrupt Controller • Controls the interrupt lines (nIRQ and nFIQ) of the ARM Processor • Thirty-two individually maskable and vectored interrupt sources – Source 0 is reserved for the Fast Interrupt Input (FIQ) – Source 1 is reserved for system peripherals (PIT, RTT, PMC, DBGU, etc.) – Programmable Edge-triggered or Level-sensitive Internal Sources – Programmable Positive/Negative Edge-triggered or High/Low Level-sensitive • Three External Sources plus the Fast Interrupt signal • 8-level Priority Controller – Drives the Normal Interrupt of the processor – Handles priority of the interrupt sources 1 to 31 – Higher priority interrupts can be served during service of lower priority interrupt • Vectoring – Optimizes Interrupt Service Routine Branch and Execution – One 32-bit Vector Register per interrupt source – Interrupt Vector Register reads the corresponding current Interrupt Vector • Protect Mode – Easy debugging by preventing automatic operations when protect modeIs are enabled • Fast Forcing – Permits redirecting any normal interrupt source on the Fast Interrupt of the processor 9.12 Debug Unit • Composed of two functions – Two-pin UART – Debug Communication Channel (DCC) support • Two-pin UART – Implemented features are 100% compatible with the standard Atmel USART – Independent receiver and transmitter with a common programmable Baud Rate Generator – Even, Odd, Mark or Space Parity Generation – Parity, Framing and Overrun Error Detection – Automatic Echo, Local Loopback and Remote Loopback Channel Modes – Support for two PDC channels with connection to receiver and transmitter • Debug Communication Channel Support – Offers visibility of and interrupt trigger from COMMRX and COMMTX signals from the ARM Processor’s ICE Interface 32 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 9.13 Chip Identification • Chip ID: – 0x329AA3A0 for the SAM9XE512 – 0x329A93A0 for the SAM9XE256 – 0x329973A0 for the SAM9XE128 • JTAG ID: 05B1_C03F • ARM926 TAP ID: 0x0792603F 33 6254CS–ATARM–08-Jan-10 10. Peripherals 10.1 User Interface The Peripherals are mapped in the upper 256 Mbytes of the address space between the addresses 0xFFFA 0000 and 0xFFFC FFFF. Each User Peripheral is allocated 16 Kbytes of address space. A complete memory map is presented in Figure 8-1 on page 20. 10.2 Peripheral Identifier The AT91SAM9XE128/256/512 embeds a wide range of peripherals. Table 10-1 defines the Peripheral Identifiers of the AT91SAM9XE128/256/512. A peripheral identifier is required for the control of the peripheral interrupt with the Advanced Interrupt Controller and for the control of the peripheral clock with the Power Management Controller. Table 10-1. Peripheral ID Peripheral Mnemonic Peripheral Name External Interrupt 0 AIC Advanced Interrupt Controller FIQ 1 SYSC System Controller Interrupt 2 PIOA Parallel I/O Controller A 3 PIOB Parallel I/O Controller B 4 PIOC Parallel I/O Controller C 5 ADC Analog-to-digital Converter 6 US0 USART 0 7 US1 USART 1 8 US2 USART 2 9 MCI Multimedia Card Interface 10 UDP USB Device Port 11 TWI0 Two Wire Interface 0 12 SPI0 Serial Peripheral Interface 0 13 SPI1 Serial Peripheral Interface1 14 SSC Synchronous Serial Controller 15 - Reserved 16 - Reserved 17 TC0 Timer/Counter 0 18 TC1 Timer/Counter 1 19 TC2 Timer/Counter 2 20 UHP USB Host Port 21 EMAC Ethernet MAC 22 ISI Image Sensor Interface 23 US3 USART 3 24 US4 USART 4 25 TWI1 Two Wire Interface 1 26 TC3 Timer/Counter 3 27 TC4 Timer/Counter 4 28 TC5 Timer/Counter 5 29 AIC Advanced Interrupt Controller IRQ0 30 AIC Advanced Interrupt Controller IRQ1 31 AIC Advanced Interrupt Controller IRQ2 Note: 34 AT91SAM9XE128/256/512 Peripheral Identifiers Setting AIC, SYSC, UHP, ADC and IRQ0-2 bits in the clock set/clear registers of the PMC has no effect. The ADC clock is automatically started for the first conversion. In Sleep Mode the ADC clock is automatically stopped after each conversion. AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 10.2.1 Peripheral Interrupts and Clock Control 10.2.1.1 System Interrupt The System Interrupt in Source 1 is the wired-OR of the interrupt signals coming from: • the SDRAM Controller • the Debug Unit • the Periodic Interval Timer • the Real-time Timer • the Watchdog Timer • the Reset Controller • the Power Management Controller • Enhanced Embedded Flash Controller The clock of these peripherals cannot be deactivated and Peripheral ID 1 can only be used within the Advanced Interrupt Controller. 10.2.1.2 10.3 External Interrupts All external interrupt signals, i.e., the Fast Interrupt signal FIQ or the Interrupt signals IRQ0 to IRQ2, use a dedicated Peripheral ID. However, there is no clock control associated with these peripheral IDs. Peripheral Signals Multiplexing on I/O Lines The AT91SAM9XE128/256/512 features 3 PIO controllers, PIOA, PIOB, PIOC, which multiplex the I/O lines of the peripheral set. Each PIO Controller controls up to 32 lines. Each line can be assigned to one of two peripheral functions, A or B. The multiplexing tables in the following sections define how the I/O lines of peripherals A and B are multiplexed on the PIO Controllers. The two columns “Function” and “Comments” have been inserted in this table for the user’s own comments; they may be used to track how pins are defined in an application. Note that some peripheral functions which are output only, might be duplicated within both tables. The column “Reset State” indicates whether the PIO Line resets in I/O mode or in peripheral mode. If I/O is mentioned, the PIO Line resets in input with the pull-up enabled, so that the device is maintained in a static state as soon as the reset is released. As a result, the bit corresponding to the PIO Line in the register PIO_PSR (Peripheral Status Register) resets low. If a signal name is mentioned in the “Reset State” column, the PIO Line is assigned to this function and the corresponding bit in PIO_PSR resets high. This is the case of pins controlling memories, in particular the address lines, which require the pin to be driven as soon as the reset is released. Note that the pull-up resistor is also enabled in this case. 35 6254CS–ATARM–08-Jan-10 10.3.1 PIO Controller A Multiplexing Table 10-2. Multiplexing on PIO Controller A PIO Controller A Application Usage Reset State Power Supply MCDB0 I/O VDDIOP0 MCCDB I/O VDDIOP0 I/O VDDIOP0 MCDB3 I/O VDDIOP0 RTS2 MCDB2 I/O VDDIOP0 PA5 CTS2 MCDB1 I/O VDDIOP0 PA6 MCDA0 I/O VDDIOP0 PA7 MCCDA I/O VDDIOP0 PA8 MCCK I/O VDDIOP0 PA9 MCDA1 I/O VDDIOP0 PA10 MCDA2 ETX2 I/O VDDIOP0 PA11 MCDA3 ETX3 I/O VDDIOP0 PA12 ETX0 I/O VDDIOP0 PA13 ETX1 I/O VDDIOP0 PA14 ERX0 I/O VDDIOP0 PA15 ERX1 I/O VDDIOP0 PA16 ETXEN I/O VDDIOP0 PA17 ERXDV I/O VDDIOP0 PA18 ERXER I/O VDDIOP0 PA19 ETXCK I/O VDDIOP0 PA20 EMDC I/O VDDIOP0 PA21 EMDIO I/O VDDIOP0 PA22 ADTRG ETXER I/O VDDIOP0 PA23 TWD0 ETX2 I/O VDDIOP0 PA24 TWCK0 ETX3 I/O VDDIOP0 PA25 TCLK0 ERX2 I/O VDDIOP0 PA26 TIOA0 ERX3 I/O VDDIOP0 PA27 TIOA1 ERXCK I/O VDDIOP0 PA28 TIOA2 ECRS I/O VDDIOP0 PA29 SCK1 ECOL I/O VDDIOP0 SCK2 RXD4 I/O VDDIOP0 I/O VDDIOP0 I/O Line Peripheral A Peripheral B PA0 SPI0_MISO PA1 SPI0_MOSI PA2 SPI0_SPCK PA3 SPI0_NPCS0 PA4 (1) PA30 (1) PA31 Note: 36 SCK0 TXD4 1. Not available in the 208-lead PQFP package. Comments Function Comments AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 10.3.2 PIO Controller B Multiplexing Table 10-3. Multiplexing on PIO Controller B PIO Controller B I/O Line Peripheral A Peripheral B PB0 SPI1_MISO PB1 Application Usage Reset State Power Supply TIOA3 I/O VDDIOP0 SPI1_MOSI TIOB3 I/O VDDIOP0 PB2 SPI1_SPCK TIOA4 I/O VDDIOP0 PB3 SPI1_NPCS0 TIOA5 I/O VDDIOP0 PB4 TXD0 I/O VDDIOP0 PB5 RXD0 I/O VDDIOP0 PB6 TXD1 TCLK1 I/O VDDIOP0 PB7 RXD1 TCLK2 I/O VDDIOP0 PB8 TXD2 I/O VDDIOP0 PB9 RXD2 I/O VDDIOP0 PB10 TXD3 ISI_D8 I/O VDDIOP1 PB11 RXD3 ISI_D9 I/O VDDIOP1 PB12(1) TWD1 ISI_D10 I/O VDDIOP1 PB13(1) TWCK1 ISI_D11 I/O VDDIOP1 PB14 DRXD I/O VDDIOP0 PB15 DTXD I/O VDDIOP0 PB16 TK TCLK3 I/O VDDIOP0 PB17 TF TCLK4 I/O VDDIOP0 PB18 TD TIOB4 I/O VDDIOP0 PB19 RD TIOB5 I/O VDDIOP0 PB20 RK ISI_D0 I/O VDDIOP1 PB21 RF ISI_D1 I/O VDDIOP1 PB22 DSR0 ISI_D2 I/O VDDIOP1 PB23 DCD0 ISI_D3 I/O VDDIOP1 PB24 DTR0 ISI_D4 I/O VDDIOP1 PB25 RI0 ISI_D5 I/O VDDIOP1 PB26 RTS0 ISI_D6 I/O VDDIOP1 PB27 CTS0 ISI_D7 I/O VDDIOP1 PB28 RTS1 ISI_PCK I/O VDDIOP1 PB29 CTS1 ISI_VSYNC I/O VDDIOP1 PB30 PCK0 ISI_HSYNC I/O VDDIOP1 PB31 PCK1 ISI_MCK I/O VDDIOP1 Note: Comments Function Comments 1. Not available in the 208-lead PQFP package. 37 6254CS–ATARM–08-Jan-10 10.3.3 PIO Controller C Multiplexing Table 10-4. Multiplexing on PIO Controller C PIO Controller C I/O Line Peripheral A Application Usage Peripheral B Comments Reset State Power Supply PC0 SCK3 AD0 I/O VDDANA PC1 PCK0 AD1 I/O VDDANA (1) PCK1 AD2 I/O VDDANA (1) SPI1_NPCS3 AD3 I/O VDDANA PC2 PC3 PC4 A23 SPI1_NPCS2 A23 VDDIOM PC5 A24 SPI1_NPCS1 A24 VDDIOM PC6 TIOB2 CFCE1 I/O VDDIOM PC7 TIOB1 CFCE2 I/O VDDIOM PC8 NCS4/CFCS0 RTS3 I/O VDDIOM PC9 NCS5/CFCS1 TIOB0 I/O VDDIOM PC10 A25/CFRNW CTS3 A25 VDDIOM PC11 NCS2 SPI0_NPCS1 I/O VDDIOM PC12(1) IRQ0 NCS7 I/O VDDIOM PC13 FIQ NCS6 I/O VDDIOM PC14 NCS3/NANDCS IRQ2 I/O VDDIOM PC15 NWAIT IRQ1 I/O VDDIOM PC16 D16 SPI0_NPCS2 I/O VDDIOM PC17 D17 SPI0_NPCS3 I/O VDDIOM PC18 D18 SPI1_NPCS1 I/O VDDIOM PC19 D19 SPI1_NPCS2 I/O VDDIOM PC20 D20 SPI1_NPCS3 I/O VDDIOM PC21 D21 EF100 I/O VDDIOM PC22 D22 TCLK5 I/O VDDIOM PC23 D23 I/O VDDIOM PC24 D24 I/O VDDIOM PC25 D25 I/O VDDIOM PC26 D26 I/O VDDIOM PC27 D27 I/O VDDIOM PC28 D28 I/O VDDIOM PC29 D29 I/O VDDIOM PC30 D30 I/O VDDIOM PC31 D31 I/O VDDIOM Note: 38 Function Comments 1. Not available in the 208-lead PQFP package. AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 10.4 10.4.1 Embedded Peripherals Serial Peripheral Interface • Supports communication with serial external devices – Four chip selects with external decoder support allow communication with up to 15 peripherals – Serial memories, such as DataFlash and 3-wire EEPROMs – Serial peripherals, such as ADCs, DACs, LCD Controllers, CAN Controllers and Sensors – External co-processors • Master or slave serial peripheral bus interface – 8- to 16-bit programmable data length per chip select – Programmable phase and polarity per chip select – Programmable transfer delays between consecutive transfers and between clock and data per chip select – Programmable delay between consecutive transfers – Selectable mode fault detection • Very fast transfers supported – Transfers with baud rates up to MCK – The chip select line may be left active to speed up transfers on the same device 10.4.2 Two-wire Interface • Master, Multi-master and Slave modes supported • General call supported in Slave mode • Connection to PDC Channel 10.4.3 USART • Programmable Baud Rate Generator • 5- to 9-bit full-duplex synchronous or asynchronous serial communications – 1, 1.5 or 2 stop bits in Asynchronous Mode or 1 or 2 stop bits in Synchronous Mode – Parity generation and error detection – Framing error detection, overrun error detection – MSB- or LSB-first – Optional break generation and detection – By 8 or by 16 oversampling receiver frequency – Hardware handshaking RTS-CTS – Receiver time-out and transmitter timeguard – Optional Multi-drop Mode with address generation and detection – Optional Manchester Encoding • RS485 with driver control signal • ISO7816, T = 0 or T = 1 Protocols for interfacing with smart cards – NACK handling, error counter with repetition and iteration limit 39 6254CS–ATARM–08-Jan-10 • IrDA modulation and demodulation – Communication at up to 115.2 Kbps • Test Modes – Remote Loopback, Local Loopback, Automatic Echo 10.4.4 Serial Synchronous Controller • Provides serial synchronous communication links used in audio and telecom applications (with CODECs in Master or Slave Modes, I2S, TDM Buses, Magnetic Card Reader, etc.) • Contains an independent receiver and transmitter and a common clock divider • Offers a configurable frame sync and data length • Receiver and transmitter can be programmed to start automatically or on detection of different event on the frame sync signal • Receiver and transmitter include a data signal, a clock signal and a frame synchronization signal 10.4.5 Timer Counter • Six 16-bit Timer Counter Channels • Wide range of functions including: – Frequency Measurement – Event Counting – Interval Measurement – Pulse Generation – Delay Timing – Pulse Width Modulation – Up/down Capabilities • Each channel is user-configurable and contains: – Three external clock inputs – Five internal clock inputs – Two multi-purpose input/output signals • Two global registers that act on all three TC Channels 10.4.6 Multimedia Card Interface • One double-channel Multimedia Card Interface • Compatibility with MultiMedia Card Specification Version 2.2 • Compatibility with SD Memory Card Specification Version 1.0 • Compatibility with SDIO Specification Version V1.0. • Cards clock rate up to Master Clock divided by 2 • Embedded power management to slow down clock rate when not used • MCI has two slot, each supporting – One slot for one MultiMediaCard bus (up to 30 cards) or – One SD Memory Card • Support for stream, block and multi-block data read and write 40 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 10.4.7 USB Host Port • Compliance with Open HCI Rev 1.0 Specification • Compliance with USB V2.0 Full-speed and Low-speed Specification • Supports both Low-Speed 1.5 Mbps and Full-speed 12 Mbps devices • Root hub integrated with two downstream USB ports in the 217-LFBGA package • Two embedded USB transceivers • Supports power management • Operates as a master on the Matrix 10.4.8 USB Device Port • USB V2.0 full-speed compliant, 12 Mbits per second • Embedded USB V2.0 full-speed transceiver • Embedded 2,688-byte dual-port RAM for endpoints • Suspend/Resume logic • Ping-pong mode (two memory banks) for isochronous and bulk endpoints • Eight general-purpose endpoints – Endpoint 0 and 3: 64 bytes, no ping-pong mode – Endpoint 1, 2, 6, 7: 64 bytes, ping-pong mode – Endpoint 4 and 5: 512 bytes, ping-pong mode • Embedded pad pull-up 10.4.9 Ethernet 10/100 MAC • Compatibility with IEEE Standard 802.3 • 10 and 100 Mbits per second data throughput capability • Full- and half-duplex operations • MII or RMII interface to the physical layer • Register Interface to address, data, status and control registers • DMA Interface, operating as a master on the Memory Controller • Interrupt generation to signal receive and transmit completion • 128-byte transmit and 128-byte receive FIFOs • Automatic pad and CRC generation on transmitted frames • Address checking logic to recognize four 48-bit addresses • Support promiscuous mode where all valid frames are copied to memory • Support physical layer management through MDIO interface control of alarm and update time/calendar data in 10.4.10 Image Sensor Interface • ITU-R BT. 601/656 8-bit mode external interface support • Support for ITU-R BT.656-4 SAV and EAV synchronization • Vertical and horizontal resolutions up to 2048 x 2048 • Preview Path up to 640*480 • Support for packed data formatting for YCbCr 4:2:2 formats • Preview scaler to generate smaller size image 41 6254CS–ATARM–08-Jan-10 10.4.11 Analog-to-digital Converter • 4-channel ADC • 10-bit 312K samples/sec. Successive Approximation Register ADC • -2/+2 LSB Integral Non Linearity, -1/+1 LSB Differential Non Linearity • Individual enable and disable of each channel • External voltage reference for better accuracy on low voltage inputs • Multiple trigger source – Hardware or software trigger – External trigger pin – Timer Counter 0 to 2 outputs TIOA0 to TIOA2 trigger • Sleep Mode and conversion sequencer – Automatic wakeup on trigger and back to sleep mode after conversions of all enabled channels • Four analog inputs shared with digital signals 42 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 11. Package Drawings Figure 11-1. 208-pin PQFP Package Drawing 43 6254CS–ATARM–08-Jan-10 Figure 11-2. 217-ball LFBGA Package Drawing 44 AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 12. AT911SAM9XE128/256/512 Ordering Information Table 12-1. AT91SAM9XE128/256/512 Ordering Information Ordering Code Package Package Type Temperature Operating Range AT91SAM9XE128-QU PQFP208 Green AT91SAM9XE128-CU BGA217 Green Industrial -40°C to 85°C AT91SAM9XE256-QU PQFP208 Green AT91SAM9XE256-CU BGA217 Green AT91SAM9XE512-QU PQFP208 Green AT91SAM9XE512-CU BGA217 Green Industrial -40°C to 85°C Industrial -40°C to 85°C 45 6254CS–ATARM–08-Jan-10 13. Revision History Doc Rev. 6254CS Change Request Ref. Comments Table 3-1, “Signal Description List”, PCKx, DBGU, AIC, PIOC, USART, SSC, TC, SPI, TWI voltage references 6401 removed. Cross reference referring to PIO Multiplexing added to these signals. Table 10-3, “Multiplexing on PIO Controller B”, PB16 to PB21, Peripheral A column updated. Table 10-4, “Multiplexing on PIO Controller C”, PC0 to PC3, Power Supply column updated. Doc. Rev 6254BS Section 8-1 “AT91SAM9XE128/256/512 Memory Mapping”, GPBR addresses changed. 6767 Section 6.1 “ERASE Pin”, ERASE pin is powered by VDDIOP0 rail. Section 7.2.2 “Matrix Slaves” and Section 7.2.3 “Masters to Slaves Access” Slave order changed in Table 7-2 and Table 7-3 Section 8.1.4 “ROM Topology”and Figure 8-2 “ROM Boot Memory Map”, added PA3. Section 8.1.4.1 “Fast Flash Programming Interface”, added PA3. Table 8-1, added PGMEN3 and PA3. Table 3-1, “Signal Description List,” PGMEN[3:0] replaces PGMEN[2:0]. Section 9.2 “Reset Controller”, added: “At reset the NRST pin is an output”. 6927 Section 8.2.5 “I/O Drive Selection”, added to datasheet. 6768 GLobal: KB rewritten as -Kbyte or Kbytes, MB as Mbytes or -Mbyte (conform to style guide; lit° 3363B) techpubs/rfo Comments Change Request Ref. Removed 6.8, Slow CLock Selection (is shown in 27.5 of the full datasheet) Removed fomer Section 5.2 “Power Consumption”. Removed Clock Generator block diagram from Section 9.5 “Clock Generator” (is shown in Figure 27.1 of the full datasheet). Removed PMC block diagram from Section 9.6 “Power Management Controller” (is shown in Figure 28.1 of the full datasheet). “Features”, “Ethernet MAC 10/100 Base-T”, 128-byte FIFOs (typo corrected). Debug Unit (DBGU), added, Mode for general purpose6-2-wire UART serial communication Section 9.13 “Chip Identification”, SAM9XE512 chip ID is 0x329AA3A0. Table 3-1, “Signal Description List,””, comment column updated in certain instances and “PIO Controller PIOA - PIOB - PIOC” , has a foot note added to its comments column. SHDWN is active Low. Section 5.1 “Power Supplies”, added “Caution: VDDCORE and VDDIO constraints....... Section 6. “I/O Line Considerations”, unneeded paragraphs removed. “Features”, “Additional Embedded Memories”Fast Read Time: 45 ns “Features”, “Four Universal Synchronous/Asynchronous Receiver Transmitters (USART)”, added Manchester Encoding/Decoding. Section 6.3 “Shutdown Logic Pins”, updated with external pull-up requirement. 6254AS 46 rfo 5800 5846 5800 rfo 5930 rfo First issue. AT91SAM9XE128/256/512 Preliminary 6254CS–ATARM–08-Jan-10 AT91SAM9XE128/256/512 Preliminary 47 6254CS–ATARM–08-Jan-10 Headquarters International Atmel Corporation 2325 Orchard Parkway San Jose, CA 95131 USA Tel: 1(408) 441-0311 Fax: 1(408) 487-2600 Atmel Asia Unit 1-5 & 16, 19/F BEA Tower, Millennium City 5 418 Kwun Tong Road Kwun Tong, Kowloon Hong Kong Tel: (852) 2245-6100 Fax: (852) 2722-1369 Atmel Europe Le Krebs 8, Rue Jean-Pierre Timbaud BP 309 78054 Saint-Quentin-enYvelines Cedex France Tel: (33) 1-30-60-70-00 Fax: (33) 1-30-60-71-11 Atmel Japan 9F, Tonetsu Shinkawa Bldg. 1-24-8 Shinkawa Chuo-ku, Tokyo 104-0033 Japan Tel: (81) 3-3523-3551 Fax: (81) 3-3523-7581 Technical Support AT91SAM Support Atmel techincal support Sales Contacts www.atmel.com/contacts/ Product Contact Web Site www.atmel.com www.atmel.com/AT91SAM Literature Requests www.atmel.com/literature Disclaimer: The information in this document is provided in connection with Atmel products. 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