Features • Incorporates the ARM920T™ ARM® Thumb® Processor – – – – • • • • • • • • • • • 200 MIPS at 180 MHz, Memory Management Unit 16-KByte Data Cache, 16-KByte Instruction Cache, Write Buffer In-circuit Emulator including Debug Communication Channel Mid-level Implementation Embedded Trace Macrocell™ (256-ball BGA Package only) Low Power: On VDDCORE 24.4 mA in Normal Mode, 520 µA in Standby Mode Additional Embedded Memories – 16K Bytes of SRAM and 128K Bytes of ROM External Bus Interface (EBI) – Supports SDRAM, Static Memory, Burst Flash, Glueless Connection to CompactFlash® and NAND Flash/SmartMedia® System Peripherals for Enhanced Performance: – Enhanced Clock Generator and Power Management Controller – Two On-chip Oscillators with Two PLLs – Very Slow Clock Operating Mode and Software Power Optimization Capabilities – Four Programmable External Clock Signals – System Timer Including Periodic Interrupt, Watchdog and Second Counter – Real-time Clock with Alarm Interrupt – Debug Unit, Two-wire UART and Support for Debug Communication Channel – Advanced Interrupt Controller with 8-level Priority, Individually Maskable Vectored Interrupt Sources, Spurious Interrupt Protected – Seven External Interrupt Sources and One Fast Interrupt Source – Four 32-bit PIO Controllers with Up to 122 Programmable I/O Lines, Input Change Interrupt and Open-drain Capability on Each Line – 20-channel Peripheral DMA Controller (PDC) Ethernet MAC 10/100 Base-T – Media Independent Interface (MII) or Reduced Media Independent Interface (RMII) – Integrated 28-byte FIFOs and Dedicated DMA Channels for Receive and Transmit USB 2.0 Full Speed (12 Mbits per second) Host Double Port – Dual On-chip Transceivers (Single Port Only on 208-lead PQFP Package) – Integrated FIFOs and Dedicated DMA Channels USB 2.0 Full Speed (12 Mbits per second) Device Port – On-chip Transceiver, 2-Kbyte Configurable Integrated FIFOs Multimedia Card Interface (MCI) – Automatic Protocol Control and Fast Automatic Data Transfers – MMC and SD Memory Card-compliant, Supports Up to Two SD Memory Cards Three 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) – Support for ISO7816 T0/T1 Smart Card – Hardware Handshaking – RS485 Support, IrDA® Up To 115 Kbps – Full Modem Control Lines on USART1 Master/Slave Serial Peripheral Interface (SPI) – 8- to 16-bit Programmable Data Length, 4 External Peripheral Chip Selects ARM920T-based Microcontroller AT91RM9200 NOTE: This is a summary document. The complete document is available on the Atmel website at www.atmel.com. 1768MS–ATARM–09-Jul-09 • Two 3-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 Two-wire Interface (TWI) – Master Mode Support, All 2-wire Atmel EEPROMs Supported IEEE® 1149.1 JTAG Boundary Scan on All Digital Pins Power Supplies – 1.65V to 1.95V for VDDCORE, VDDOSC and VDDPLL – 3.0V to 3.6V for VDDIOP (Peripheral I/Os) and for VDDIOM (Memory I/Os) Available in a 208-pin Green PQFP or 256-ball RoHS-compliant BGA Package 1. Description The AT91RM9200 is a complete system-on-chip built around the ARM920T ARM Thumb processor. It incorporates a rich set of system and application peripherals and standard interfaces in order to provide a single-chip solution for a wide range of compute-intensive applications that require maximum functionality at minimum power consumption at lowest cost. The AT91RM9200 incorporates a high-speed on-chip SRAM workspace, and a low-latency External Bus Interface (EBI) for seamless connection to whatever configuration of off-chip memories and memory-mapped peripherals is required by the application. The EBI incorporates controllers for synchronous DRAM (SDRAM), Burst Flash and Static memories and features specific circuitry facilitating the interface for NAND Flash/SmartMedia and Compact Flash. The Advanced Interrupt Controller (AIC) enhances the interrupt handling performance of the ARM920T processor by providing multiple vectored, prioritized interrupt sources and reducing the time taken to transfer to an interrupt handler. The Peripheral DMA Controller (PDC) provides DMA channels for all the serial peripherals, enabling them to transfer data to or from on- and off-chip memories without processor intervention. This reduces the processor overhead when dealing with transfers of continuous data streams.The AT91RM9200 benefits from a new generation of PDC which includes dual pointers that simplify significantly buffer chaining. The set of Parallel I/O (PIO) controllers multiplex the peripheral input/output lines with generalpurpose data I/Os for maximum flexibility in device configuration. An input change interrupt, open drain capability and programmable pull-up resistor is included on each line. The Power Management Controller (PMC) keeps system power consumption to a minimum by selectively enabling/disabling the processor and various peripherals under software control. It uses an enhanced clock generator to provide a selection of clock signals including a slow clock (32 kHz) to optimize power consumption and performance at all times. The AT91RM9200 integrates a wide range of standard interfaces including USB 2.0 Full Speed Host and Device and Ethernet 10/100 Base-T Media Access Controller (MAC), which provides connection to a extensive range of external peripheral devices and a widely used networking layer. In addition, it provides an extensive set of peripherals that operate in accordance with several industry standards, such as those used in audio, telecom, Flash Card, infrared and Smart Card applications. To complete the offer, the AT91RM9200 benefits from the integration of a wide range of debug features including JTAG-ICE, a dedicated UART debug channel (DBGU) and an embedded real time trace. This enables the development and debug of all applications, especially those with real-time constraints. 2 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 2. Block Diagram Bold arrows ( AT91RM9200 Block Diagram NRST Reset and Test IRQ0-IRQ6 JTAG Scan ETM Instruction Cache 16K bytes MMU PLLRCB AIC Fast SRAM 16K bytes Address Decoder EBI Fast ROM 128K bytes PLLA XIN PMC OSC XOUT Misalignment Detector Bus Arbiter Peripheral Bridge System Timer Peripheral DMA Controller XIN32 OSC XOUT32 DRXD CompactFlash NAND Flash SmartMedia Abort Status PLLB PLLRCA SDRAM Controller Memory Controller Burst Flash Controller RTC Static Memory Controller DBGU PIO PDC PIOA/PIOB/PIOC/PIOD Controller DDM DDP MCCK MCCDA MCDA0-MCDA3 MCCDB MCDB0-MCDB3 FIFO USB Host DMA HDMA HDPA HDMB HDPB FIFO ETXCK-ERXCK-EREFCK ETXEN-ETXER ECRS-ECOL ERXER-ERXDV ERX0-ERX3 ETX0-ETX3 EMDC EMDIO EF100 Ethernet MAC 10/100 PDC APB SSC0 TF0 TK0 TD0 RD0 RK0 RF0 SSC1 TF1 TK1 TD1 RD1 RK1 RF1 USART0 PDC PDC PDC USART2 RXD3 TXD3 SCK3 RTS3 CTS3 USART3 PDC SSC2 PDC PDC Timer Counter PDC TC0 TC1 TC2 PIO PIO PIO USART1 RXD2 TXD2 SCK2 RTS2 CTS2 TF2 TK2 TD2 RD2 RK2 RF2 TCLK0 TCLK1 TCLK2 TIOA0 TIOB0 TIOA1 TIOB1 TIOA2 TIOB2 SPI Timer Counter PDC TC3 TWD TWI TWCK D0-D15 A0/NBS0 A1/NBS2/NWR2 A2-A15/A18-A22 A16/BA0 A17/BA1 NCS0/BFCS NCS1/SDCS NCS2 NCS3/SMCS NRD/NOE/CFOE NWR0/NWE/CFWE NWR1/NBS1/CFIOR NWR3/NBS3/CFIOW SDCK SDCKE RAS-CAS SDWE SDA10 BFRDY/SMOE BFCK BFAVD BFBAA/SMWE BFOE BFWE A23-A24 A25/CFRNW NWAIT NCS4/CFCS NCS5/CFCE1 NCS6/CFCE2 NCS7 D16-D31 USB Device MCI RXD0 TXD0 SCK0 RTS0 CTS0 NPCS0 NPCS1 NPCS2 NPCS3 MISO MOSI SPCK FIFO Transceiver Transceiver DMA RXD1 TXD1 SCK1 RTS1 CTS1 DSR1 DTR1 DCD1 RI1 TPS0 - TPS2 TPK0 - TPK15 Data Cache 16K bytes PCK0-PCK3 DTXD TCLK BMS PIO FIQ TSYNC ARM920T Core ICE JTAGSEL TDI TDO TMS TCK NTRST PIO TST0-TST1 PIO Figure 2-1. ) indicate master-to-slave dependency. TC4 TC5 TCLK3 TCLK4 TCLK5 TIOA3 TIOB3 TIOA4 TIOB4 TIOA5 TIOB5 3 1768MS–ATARM–09-Jul-09 3. Signal Description Table 3-1. Pin Name Signal Description by Peripheral Function Type Active Level Comments Power VDDIOM Memory I/O Lines Power Supply Power 3.0V to 3.6V VDDIOP Peripheral I/O Lines Power Supply Power 3.0V to 3.6V VDDPLL Oscillator and PLL Power Supply Power 1.65V to 1.95V VDDCORE Core Chip Power Supply Power 1.65V to 1.95V VDDOSC Oscillator Power Supply Power 1.65V to 1.95V GND Ground Ground GNDPLL PLL Ground Ground GNDOSC Oscillator Ground Ground XIN Main Crystal Input XOUT Main Crystal Output XIN32 32KHz Crystal Input XOUT32 32KHz Crystal Output PLLRCA PLL A Filter PLLRCB PLL B Filter PCK0 - PCK3 Programmable Clock Output Clocks, Oscillators and PLLs Input Output Input Output Input Input Output ICE and JTAG TCK Test Clock Input Schmitt trigger TDI Test Data In Input Internal Pull-up, Schmitt trigger TDO Test Data Out Output TMS Test Mode Select Input NTRST Test Reset Signal Input JTAGSEL JTAG Selection Input Tri-state Internal Pull-up, Schmitt trigger Low Internal Pull-up, Schmitt trigger Schmitt trigger ETM™ TSYNC Trace Synchronization Signal Output TCLK Trace Clock Output TPS0 - TPS2 Trace ARM Pipeline Status Output TPK0 - TPK15 Trace Packet Port Output Reset/Test NRST Microcontroller Reset Input TST0 - TST1 Test Mode Select Input 4 Low No on-chip pull-up, Schmitt trigger Must be tied low for normal operation, Schmitt trigger AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 Table 3-1. Signal Description by Peripheral Pin Name Function Type Active Level Comments Memory Controller BMS Boot Mode Select Input Debug Unit DRXD Debug Receive Data Input Debug Receive Data DTXD Debug Transmit Data Output Debug Transmit Data AIC IRQ0 - IRQ6 External Interrupt Inputs Input FIQ Fast Interrupt Input Input PIO PA0 - PA31 Parallel IO Controller A I/O Pulled-up input at reset PB0 - PB29 Parallel IO Controller B I/O Pulled-up input at reset PC0 - PC31 Parallel IO Controller C I/O Pulled-up input at reset PD0 - PD27 Parallel IO Controller D I/O Pulled-up input at reset I/O Pulled-up input at reset EBI D0 - D31 Data Bus A0 - A25 Address Bus Output 0 at reset SMC NCS0 - NCS7 Chip Select Lines Output Low 1 at reset NWR0 - NWR3 Write Signal Output Low 1 at reset NOE Output Enable Output Low 1 at reset NRD Read Signal Output Low 1 at reset NUB Upper Byte Select Output Low 1 at reset NLB Lower Byte Select Output Low 1 at reset NWE Write Enable Output Low 1 at reset NWAIT Wait Signal Input Low NBS0 - NBS3 Byte Mask Signal Output Low 1 at reset EBI for CompactFlash Support CFCE1 - CFCE2 CompactFlash Chip Enable Output Low CFOE CompactFlash Output Enable Output Low CFWE CompactFlash Write Enable Output Low CFIOR CompactFlash IO Read Output Low CFIOW CompactFlash IO Write Output Low CFRNW CompactFlash Read Not Write Output CFCS CompactFlash Chip Select Output Low 5 1768MS–ATARM–09-Jul-09 Table 3-1. Signal Description by Peripheral Pin Name Function Type Active Level Comments EBI for NAND Flash/SmartMedia Support SMCS NAND Flash/SmartMedia Chip Select Output Low SMOE NAND Flash/SmartMedia Output Enable Output Low SMWE NAND Flash/SmartMedia Write Enable Output Low SDRAM Controller SDCK SDRAM Clock Output SDCKE SDRAM Clock Enable Output High SDCS SDRAM Controller Chip Select Output Low BA0 - BA1 Bank Select Output SDWE SDRAM Write Enable Output Low RAS - CAS Row and Column Signal Output Low SDA10 SDRAM Address 10 Line Output Burst Flash Controller BFCK Burst Flash Clock Output BFCS Burst Flash Chip Select Output Low BFAVD Burst Flash Address Valid Output Low BFBAA Burst Flash Address Advance Output Low BFOE Burst Flash Output Enable Output Low BFRDY Burst Flash Ready Input High BFWE Burst Flash Write Enable Output Low Multimedia Card Interface MCCK Multimedia Card Clock Output MCCDA Multimedia Card A Command I/O MCDA0 - MCDA3 Multimedia Card A Data I/O MCCDB Multimedia Card B Command I/O MCDB0 - MCDB3 Multimedia Card B Data I/O USART SCK0 - SCK3 Serial Clock TXD0 - TXD3 Transmit Data Output RXD0 - RXD3 Receive Data Input RTS0 - RTS3 Ready To Send Output CTS0 - CTS3 Clear To Send Input DSR1 Data Set Ready Input DTR1 Data Terminal Ready DCD1 Data Carrier Detect Input RI1 Ring Indicator Input 6 I/O Output AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 Table 3-1. Signal Description by Peripheral Pin Name Function Type Active Level Comments USB Device Port DDM USB Device Port Data - Analog DDP USB Device Port Data + Analog USB Host Port HDMA USB Host Port A Data - Analog HDPA USB Host Port A Data + Analog HDMB USB Host Port B Data - Analog HDPB USB Host Port B Data + Analog Ethernet MAC EREFCK Reference Clock Input RMII only ETXCK Transmit Clock Input MII only ERXCK Receive Clock Input MII only ETXEN Transmit Enable Output ETX0 - ETX3 Transmit Data Output ETX0 - ETX1 only in RMII ETXER Transmit Coding Error Output MII only ERXDV Receive Data Valid Input MII only ECRSDV Carrier Sense and Data Valid Input RMII only ERX0 - ERX3 Receive Data Input ERX0 - ERX1 only in RMII ERXER Receive Error Input ECRS Carrier Sense Input MII only ECOL Collision Detected Input MII only EMDC Management Data Clock EMDIO Management Data Input/Output EF100 Force 100 Mbits/sec. Output I/O Output High RMII only Synchronous Serial Controller TD0 - TD2 Transmit Data Output RD0 - RD2 Receive Data Input TK0 - TK2 Transmit Clock I/O RK0 - RK2 Receive Clock I/O TF0 - TF2 Transmit Frame Sync I/O RF0 - RF2 Receive Frame Sync I/O Timer/Counter TCLK0 - TCLK5 External Clock Input Input TIOA0 - TIOA5 I/O Line A I/O TIOB0 - TIOB5 I/O Line B I/O 7 1768MS–ATARM–09-Jul-09 Table 3-1. Signal Description by Peripheral Pin Name Function Type Active Level Comments SPI MISO Master In Slave Out I/O MOSI Master Out Slave In I/O SPCK SPI Serial Clock I/O NPCS0 SPI Peripheral Chip Select 0 I/O Low NPCS1 - NPCS3 SPI Peripheral Chip Select Output Low Two-Wire Interface TWD Two-wire Serial Data I/O TWCK Two-wire Serial Clock I/O 4. Package and Pinout The AT91RM9200 is available in two packages: • 208-pin PQFP, 31.2 x 31.2 mm, 0.5 mm pitch • 256-ball BGA, 15 x 15 mm, 0.8 mm ball pitch The product features of the 256-ball BGA package are extended compared to the 208-lead PQFP package. The features that are available only with the 256-ball BGA package are: • Parallel I/O Controller D • ETM port with outputs multiplexed on the PIO Controller D • a second USB Host transceiver, opening the Hub capabilities of the embedded USB Host. 4.1 208-pin PQFP Package Outline Figure 1-1 shows the orientation of the 208-pin PQFP package. A detailed mechanical description is given in the section “AT91RM9200 Mechanical Characteristics” of the product datasheet. Figure 4-1. 208-pin PQFP Package (Top View) 156 105 104 157 208 53 1 8 52 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 4.2 208-pin PQFP Package Pinout Table 4-1. AT91RM9200 Pinout for 208-pin PQFP Package Pin Number Signal Name Pin Number Signal Name Pin Number Signal Name Pin Number Signal Name 1 PC24 37 VDDPLL 73 PA27 109 TMS 2 PC25 38 PLLRCB 74 PA28 110 NTRST 3 PC26 39 GNDPLL 75 VDDIOP 111 VDDIOP 4 PC27 40 VDDIOP 76 GND 112 GND 5 PC28 41 GND 77 PA29 113 TST0 6 PC29 42 PA0 78 PA30 114 TST1 7 VDDIOM 43 PA1 79 PA31/BMS 115 NRST 8 GND 44 PA2 80 PB0 116 VDDCORE 9 PC30 45 PA3 81 PB1 117 GND 10 PC31 46 PA4 82 PB2 118 PB23 11 PC10 47 PA5 83 PB3 119 PB24 12 PC11 48 PA6 84 PB4 120 PB25 13 PC12 49 PA7 85 PB5 121 PB26 14 PC13 50 PA8 86 PB6 122 PB27 15 PC14 51 PA9 87 PB7 123 PB28 16 PC15 52 PA10 88 PB8 124 PB29 17 PC0 53 PA11 89 PB9 125 HDMA 18 PC1 54 PA12 90 PB10 126 HDPA 19 VDDCORE 55 PA13 91 PB11 127 DDM 20 GND 56 VDDIOP 92 PB12 128 DDP 21 PC2 57 GND 93 VDDIOP 129 VDDIOP 22 PC3 58 PA14 94 GND 130 GND 23 PC4 59 PA15 95 PB13 131 VDDIOM 24 PC5 60 PA16 96 PB14 132 GND 25 PC6 61 PA17 97 PB15 133 A0/NBS0 26 VDDIOM 62 VDDCORE 98 PB16 134 A1/NBS2/NWR2 27 GND 63 GND 99 PB17 135 A2 28 VDDPLL 64 PA18 100 PB18 136 A3 29 PLLRCA 65 PA19 101 PB19 137 A4 30 GNDPLL 66 PA20 102 PB20 138 A5 31 XOUT 67 PA21 103 PB21 139 A6 32 XIN 68 PA22 104 PB22 140 A7 33 VDDOSC 69 PA23 105 JTAGSEL 141 A8 34 GNDOSC 70 PA24 106 TDI 142 A9 35 XOUT32 71 PA25 107 TDO 143 A10 36 XIN32 72 PA26 108 TCK 144 SDA10 9 1768MS–ATARM–09-Jul-09 Table 4-1. AT91RM9200 Pinout for 208-pin PQFP Package (Continued) Pin Number Signal Name Pin Number Signal Name Pin Number Signal Name Pin Number Signal Name 145 A11 161 PC7 177 CAS 193 D10 146 VDDIOM 162 PC8 178 SDWE 194 D11 147 GND 163 PC9 179 D0 195 D12 148 A12 164 VDDIOM 180 D1 196 D13 149 A13 165 GND 181 D2 197 D14 150 A14 166 NCS0/BFCS 182 D3 198 D15 151 A15 167 NCS1/SDCS 183 VDDIOM 199 VDDIOM 152 VDDCORE 168 NCS2 184 GND 200 GND 153 GND 169 NCS3/SMCS 185 D4 201 PC16 154 A16/BA0 170 NRD/NOE/CFOE 186 D5 202 PC17 155 A17/BA1 171 NWR0/NWE/CFWE 187 D6 203 PC18 156 A18 172 NWR1/NBS1/CFIOR 188 VDDCORE 204 PC19 157 A19 173 NWR3/NBS3/CFIOW 189 GND 205 PC20 158 A20 174 SDCK 190 D7 206 PC21 159 A21 175 SDCKE 191 D8 207 PC22 160 A22 176 RAS 192 D9 208 PC23 Note: 1. Shaded cells define the pins powered by VDDIOM. 4.3 256-ball BGA Package Outline Figure 4-2 shows the orientation of the 256-ball LFBGA package. A detailed mechanical description is given in the section “AT91RM9200 Mechanical Characteristics” of the product datasheet. Figure 4-2. 256-ball LFBGA Package (Top View) 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 BALL A1 10 A B C D E F G H J K L M N P R T U AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 4.4 256-ball BGA Package Pinout Table 4-2. AT91RM9200 Pinout for 256-ball BGA Package Pin Signal Name Pin Signal Name Pin Signal Name Pin Signal Name A1 TDI C3 PD14 E5 TCK G14 PA1 A2 JTAGSEL C4 PB22 E6 GND G15 PA2 A3 PB20 C5 PB19 E7 PB15 G16 PA3 A4 PB17 C6 PD10 E8 GND G17 XIN32 A5 PD11 C7 PB13 E9 PB7 H1 PD23 A6 PD8 C8 PB12 E10 PB3 H2 PD20 A7 VDDIOP C9 PB6 E11 PA29 H3 PD22 A8 PB9 C10 PB1 E12 PA26 H4 PD21 A9 PB4 C11 GND E13 PA25 H5 VDDIOP A10 PA31/BMS C12 PA20 E14 PA9 H13 VDDPLL A11 VDDIOP C13 PA18 E15 PA6 H14 VDDIOP A12 PA23 C14 VDDCORE E16 PD3 H15 GNDPLL A13 PA19 C15 GND E17 PD0 H16 GND A14 GND C16 PA8 F1 PD16 H17 XOUT32 A15 PA14 C17 PD5 F2 GND J1 PD25 A16 VDDIOP D1 TST1 F3 PB23 J2 PD27 A17 PA13 D2 VDDIOP F4 PB25 J3 PD24 B1 TDO D3 VDDIOP F5 PB24 J4 PD26 B2 PD13 D4 GND F6 VDDCORE J5 PB28 B3 PB18 D5 VDDIOP F7 PB16 J6 PB29 B4 PB21 D6 PD7 F9 PB11 J12 GND B5 PD12 D7 PB14 F11 PA30 J13 GNDOSC B6 PD9 D8 VDDIOP F12 PA28 J14 VDDOSC B7 GND D9 PB8 F13 PA4 J15 VDDPLL B8 PB10 D10 PB2 F14 PD2 J16 GNDPLL B9 PB5 D11 GND F15 PD1 J17 XIN B10 PB0 D12 PA22 F16 PA5 K1 HDPA B11 VDDIOP D13 PA21 F17 PLLRCB K2 DDM B12 PA24 D14 PA16 G1 PD19 K3 HDMA B13 PA17 D15 PA10 G2 PD17 K4 VDDIOP B14 PA15 D16 PD6 G3 GND K5 DDP B15 PA11 D17 PD4 G4 PB26 K13 PC5 B16 PA12 E1 NRST G5 PD18 K14 PC4 B17 PA7 E2 NTRST G6 PB27 K15 PC6 C1 TMS E3 GND G12 PA27 K16 VDDIOM C2 PD15 E4 TST0 G13 PA0 K17 XOUT 11 1768MS–ATARM–09-Jul-09 Table 4-2. AT91RM9200 Pinout for 256-ball BGA Package (Continued) Pin Signal Name Pin Signal Name Pin Signal Name Pin Signal Name L1 GND N2 A5 P13 D15 T7 NWR1/NBS1/ CFIOR L2 HDPB N3 A9 P14 PC26 T8 SDWE L3 HDMB N4 A4 P15 PC27 T9 GND L4 A6 N5 A14 P16 VDDIOM T10 VDDCORE L5 GND N6 SDA10 P17 GND T11 D9 L6 VDDIOP N7 A8 R1 GND T12 D12 L12 PC10 N8 A21 R2 GND T13 GND L13 PC15 N9 NRD/NOE/CFOE R3 A18 T14 PC19 L14 PC2 N10 RAS R4 A20 T15 PC21 L15 PC3 N11 D2 R5 PC8 T16 PC23 L16 VDDCORE N12 GND R6 VDDIOM T17 PC25 L17 PLLRCA N13 PC28 R7 NCS3/SMCS U1 VDDCORE M1 VDDIOM N14 PC31 R8 NWR3/NBS3/ CFIOW U2 GND M2 GND N15 PC30 R9 D0 U3 A16/BA0 M3 A3 N16 PC11 R10 VDDIOM U4 A19 M4 A1/NBS2/NWR2 N17 PC12 R11 D8 U5 GND M5 A10 P1 A7 R12 D13 U6 NCS0/BFCS M6 A2 P2 A13 R13 PC17 U7 SDCK M7 GND P3 A12 R14 VDDIOM U8 CAS M9 NCS1/SDCS P4 VDDIOM R15 PC24 U9 D3 M11 D4 P5 A11 R16 PC29 U10 D6 M12 GND P6 A22 R17 VDDIOM U11 D7 M13 PC13 P7 PC9 T1 A15 U12 D11 M14 PC1 P8 NWR0/NWE/CFWE T2 VDDCORE U13 D14 M15 PC0 P9 SDCKE T3 A17/BA1 U14 PC16 M16 GND P10 D1 T4 PC7 U15 PC18 M17 PC14 P11 D5 T5 VDDIOM U16 PC20 N1 A0/NBS0 P12 D10 T6 NCS2 U17 PC22 Note: 12 1. Shaded cells define the balls powered by VDDIOM. AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 5. Power Considerations 5.1 Power Supplies The AT91RM9200 has five types of power supply pins: • VDDCORE pins. They power the core, including processor, memories and peripherals; voltage ranges from 1.65V to 1.95V, 1.8V nominal. • VDDIOM pins. They power the External Bus Interface I/O lines; voltage ranges from 3.0V to 3.6V, 3V or 3.3V nominal. • VDDIOP pins. They power the Peripheral I/O lines and the USB transceivers; voltage ranges from 3.0V to 3.6V, 3V or 3.3V nominal. • VDDPLL pins. They power the PLL cells; voltage ranges from 1.65V to 1.95V, 1.8V nominal. • VDDOSC pin. They power both oscillators; voltage ranges from 1.65V to 1.95V, 1.8V nominal. The double power supplies VDDIOM and VDDIOP are identified in Table 4-1 on page 9 and Table 4-2 on page 11. These supplies enable the user to power the device differently for interfacing with memories and for interfacing with peripherals. Ground pins are common to all power supplies, except VDDPLL and VDDOSC pins. For these pins, GNDPLL and GNDOSC are provided, respectively. 5.2 Power Consumption The AT91RM9200 consumes about 500 µA of static current on VDDCORE at 25⋅ C. For dynamic power consumption, the AT91RM9200 consumes a maximum of 25 mA on VDDCORE at maximum speed in typical conditions (1.8V, 25⋅ C), processor running full-performance algorithm. 6. I/O Considerations 6.1 JTAG Port Pins TMS and TDI are Schmitt trigger inputs and integrate internal pull-up resistors of 15 kOhm typical. TCK is a Schmitt trigger input without internal pull-up resistor. TDO is a tri-state output. The JTAGSEL pin is used to select the JTAG boundary scan when asserted at a high level. The NTRST pin is used to initialize the EmbeddedICE™ TAP Controller. 6.2 Test Pin The TST0 and TST1 pins are used for manufacturing test purposes when asserted high. As they do not integrate a pull-down resistor, they must be tied low during normal operations. Driving this line at a high level leads to unpredictable results. 6.3 Reset Pin NRST is a Schmitt trigger without pull-up resistor. The NRST signal is inserted in the Boundary Scan. 13 1768MS–ATARM–09-Jul-09 6.4 PIO Controller A, B, C and D Lines All the I/O lines PA0 to PA31, PB0 to PB29, PC0 to PC31 and PD0 to PD27 integrate a programmable pull-up resistor of 15 kOhm typical. 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 must be enabled as peripherals at reset. This is explicitly indicated in the column "Reset State" of the PIO Controller multiplexing tables. 7. Processor and Architecture 7.1 ARM920T Processor • ARM9TDMI™-based on ARM Architecture v4T • Two instruction sets – ARM High-performance 32-bit Instruction Set – Thumb High Code Density 16-bit Instruction Set • 5-Stage Pipeline Architecture: – Instruction Fetch (F) – Instruction Decode (D) – Execute (E) – Data Memory (M) – Register Write (W) • 16-Kbyte Data Cache, 16-Kbyte Instruction Cache – Virtually-addressed 64-way Associative Cache – 8 words per line – Write-though and write-back operation – Pseudo-random or Round-robin replacement – Low-power CAM RAM implementation • Write Buffer – 16-word Data Buffer – 4-address Address Buffer – Software Control Drain • Standard ARMv4 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 pages – 16 embedded domains – 64 Entry Instruction TLB and 64 Entry Data TLB 8-, 16-, 32-bit Data Bus for Instructions and Data 7.2 Debug and Test • Integrated EmbeddedICE 14 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 • Debug Unit – Two-pin UART – Debug Communication Channel – Chip ID Register • Embedded Trace Macrocell: ETM9™ Rev2a – Medium Level Implementation – Half-rate Clock Mode – Four Pairs of Address Comparators – Two Data Comparators – Eight Memory Map Decoder Inputs – Two Counters – One Sequencer – One 18-byte FIFO • IEEE1149.1 JTAG Boundary Scan on all Digital Pins 7.3 Boot Program • Default Boot Program stored in ROM-based products • Downloads and runs an application from external storage media into internal SRAM • Downloaded code size depends on embedded SRAM size • Automatic detection of valid application • Bootloader supporting a wide range of non-volatile memories – SPI DataFlash® connected on SPI NPCS0 – Two-wire EEPROM – 8-bit parallel memories on NCS0 • Boot Uploader in case no valid program is detected in external NVM and supporting several communication media • Serial communication on a DBGU (XModem protocol) • USB Device Port (DFU Protocol) 7.4 Embedded Software Services • Compliant with ATPCS • Compliant with AINSI/ISO Standard C • Compiled in ARM/Thumb Interworking • ROM Entry Service • Tempo, Xmodem and DataFlash services • CRC and Sine tables 7.5 Memory Controller • Programmable Bus Arbiter handling four Masters – Internal Bus is shared by ARM920T, PDC, USB Host Port and Ethernet MAC Masters – Each Master can be assigned a priority between 0 and 7 15 1768MS–ATARM–09-Jul-09 • Address Decoder provides selection for – Eight external 256-Mbyte memory areas – Four internal 1-Mbyte memory areas – One 256-Mbyte embedded peripheral area • Boot Mode Select Option – Non-volatile Boot Memory can be internal or external – Selection is made by BMS pin sampled at reset • Abort Status Registers – Source, Type and all parameters of the access leading to an abort are saved • Misalignment Detector – Alignment checking of all data accesses – Abort generation in case of misalignment • Remap command – Provides remapping of an internal SRAM in place of the boot NVM 16 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 8. Memories Figure 8-1. AT91RM9200 Memory Mapping Internal Memory Mapping Address Memory Space 0x0000 0000 0x0000 0000 Boot Memory (1) Internal Memories 256M Bytes ROM 1 MBytes SRAM 1 MBytes USB Host User Interface 1 MBytes 0x0FFF FFFF 0x1000 0000 1 MBytes 0x0010 0000 0x0020 0000 EBI Chip Select 0 / BFC 0x1FFF FFFF 256M Bytes 0x0030 0000 0x2000 0000 EBI Chip Select 1 / SDRAMC 0x2FFF FFFF 0x0040 0000 256M Bytes Notes : Undefined (Abort) 0x3000 0000 EBI Chip Select 2 256M Bytes EBI Chip Select 3 / NANDFlash Logic 256M Bytes EBI Chip Select 4 / CF Logic 256M Bytes 248 MBytes (1) Can be SRAM, ROM or Flash depending on BMS and the REMAP Command 0x0FFF FFFF 0x3FFF FFFF 0x4000 0000 0x4FFF FFFF 0x5000 0000 0x5FFF FFFF User Peripheral Mapping 0xF000 0000 0x6000 0000 EBI Chip Select 5 / CF Logic 0x6FFF FFFF Reserved 256M Bytes 0xFFFA 0000 TCO, TC1, TC2 16K Bytes TC3, TC4, TC5 16K Bytes Reserved 16K Bytes UDP 16K Bytes MCI 16K Bytes TWI 16K Bytes EMAC 16K Bytes USART0 16K Bytes USART1 16K Bytes USART2 16K Bytes USART3 16K Bytes SSC0 16K Bytes SSC1 16K Bytes SSC2 16K Bytes 0x7000 0000 0xFFFA 4000 EBI Chip Select 6 / CF Logic 0x7FFF FFFF 256M Bytes 0xFFFA 8000 0x8000 0000 EBI Chip Select 7 256M Bytes 0x8FFF FFFF 0xFFFB 0000 0xFFFB 4000 0x9000 0000 System Peripheral Mapping 0xFFFB 8000 0xFFFE 4000 0xFFFB C000 Reserved 0xFFFC 0000 0xFFFF F000 0xFFFC 4000 0xFFFC 8000 Undefined (Abort) 1,518M Bytes 16K Bytes 0xFFFF FFFF 0xFFFF FFFF 512 Bytes PIOC 512 bytes PIOD 512 bytes PMC 256 Bytes ST 256 Bytes RTC 256 Bytes MC 256 Bytes 0xFFFF FE00 0xFFFE 4000 Reserved PIOB 0xFFFF FD00 0xFFFE 0000 256M Bytes 512 Bytes 0xFFFF FC00 0xFFFD C000 Internal Peripherals PIOA 0xFFFF FA00 0xFFFD 8000 0xEFFF FFFF 512 Bytes 0xFFFF F800 0xFFFD 4000 0xF000 0000 DBGU 0xFFFF F600 0xFFFD 0000 SPI 512 Bytes 0xFFFF F400 0xFFFC C000 Reserved AIC 0xFFFF F200 0xFFFF FF00 0xFFFF FFFF 17 1768MS–ATARM–09-Jul-09 A first level of address decoding is performed by the Memory Controller, i.e., by the implementation of the Advanced System Bus (ASB) with additional features. Decoding splits the 4G bytes of address space into 16 areas of 256M bytes. The areas 1 to 8 are directed to the EBI that associates these areas to the external chip selects NC0 to NCS7. The area 0 is reserved for the addressing of the internal memories, and a second level of decoding provides 1M bytes of internal memory area. The area 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. 8.1 8.1.1 Embedded Memories Internal Memory Mapping 8.1.1.1 Internal RAM The AT91RM9200 integrates a high-speed, 16-Kbyte internal SRAM. After reset and until the Remap Command is performed, the SRAM is only accessible at address 0x20 0000. After Remap, the SRAM is also available at address 0x0. 8.1.1.2 Internal ROM The AT91RM9200 integrates a 128-Kbyte Internal ROM. At any time, the ROM is mapped at address 0x10 0000. It is also accessible at address 0x0 after reset and before the Remap Command if the BMS is tied high during reset. 8.1.1.3 USB Host Port The AT91RM9200 integrates a USB Host Port Open Host Controller Interface (OHCI). The registers of this interface are directly accessible on the ASB Bus and are mapped like a standard internal memory at address 0x30 0000. 18 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 9. System Peripherals A complete memory map is shown in Figure 8-1 on page 17. 9.1 Reset Controller • Two reset input lines (NRST and NTRST) providing, respectively: • Initialization of the User Interface registers (defined in the user interface of each peripheral) and: – Sample the signals needed at bootup – Compel the processor to fetch the next instruction at address zero • Initialization of the embedded ICE TAP controller 9.2 Advanced Interrupt Controller • Controls the interrupt lines (nIRQ and nFIQ) of an 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 (ST, RTC, PMC, DBGU…) – Source 2 to Source 31 control thirty embedded peripheral interrupts or external interrupts – Programmable Edge-triggered or Level-sensitive Internal Sources – Programmable Positive/Negative Edge-triggered or High/Low Level-sensitive External Sources • 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 • General Interrupt Mask – Provides processor synchronization on events without triggering an interrupt 9.3 Power Management Controller • Optimizes the power consumption of the whole system • Embeds and controls: – One Main Oscillator and One Slow Clock Oscillator (32.768Hz) – Two Phase Locked Loops (PLLs) and Dividers – Clock Prescalers • Provides: – the Processor Clock PCK 19 1768MS–ATARM–09-Jul-09 – the Master Clock MCK – the USB Clocks, UHPCK and UDPCK, respectively for the USB Host Port and the USB Device Port – Programmable automatic PLL switch-off in USB Device suspend conditions – up to thirty peripheral clocks – four programmable clock outputs PCK0 to PCK3 • Four operating modes: – Normal Mode, Idle Mode, Slow Clock Mode, Standby Mode 9.4 Debug Unit • System peripheral to facilitate debug of Atmel’s ARM-based systems • Composed of the following functions – Two-pin UART – Debug Communication Channel (DCC) support – Chip ID Registers • 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 – Interrupt generation – Support for two PDC channels with connection to receiver and transmitter • Debug Communication Channel Support – Offers visibility of COMMRX and COMMTX signals from the ARM Processor – Interrupt generation • Chip ID Registers – Identification of the device revision, sizes of the embedded memories, set of peripherals 9.5 PIO Controller • Up to 32 programmable I/O Lines • Fully programmable through Set/Clear Registers • Multiplexing of two peripheral functions per I/O Line • For each I/O Line (whether assigned to a peripheral or used as general purpose I/O) – Input change interrupt – Glitch filter – Multi-drive option enables driving in open drain – Programmable pull up on each I/O line – Pin data status register, supplies visibility of the level on the pin at any time 20 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 • Synchronous output, provides Set and Clear of several I/O lines in a single write 10. User Peripherals 10.1 User Interface The User Peripherals are mapped in the upper 256M bytes of the address space, between the addresses 0xFFFA 0000 and 0xFFFE 3FFF. Each peripheral has a 16-Kbyte address space. A complete memory map is presented in Figure 8-1 on page 17. 10.2 Peripheral Identifiers The AT91RM9200 embeds a wide range of peripherals. Table 10-1 defines the peripheral identifiers of the AT91RM9200. 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 Identifiers Peripheral Peripheral Peripheral External ID Mnemonic Name Interrupt 0 AIC Advanced Interrupt Controller FIQ 1 SYSIRQ 2 PIOA Parallel I/O Controller A 3 PIOB Parallel I/O Controller B 4 PIOC Parallel I/O Controller C 5 PIOD Parallel I/O Controller D 6 US0 USART 0 7 US1 USART 1 8 US2 USART 2 9 US3 USART 3 10 MCI Multimedia Card Interface 11 UDP USB Device Port 12 TWI Two-wire Interface 13 SPI Serial Peripheral Interface 14 SSC0 Synchronous Serial Controller 0 15 SSC1 Synchronous Serial Controller 1 16 SSC2 Synchronous Serial Controller 2 17 TC0 Timer/Counter 0 18 TC1 Timer/Counter 1 19 TC2 Timer/Counter 2 20 TC3 Timer/Counter 3 21 TC4 Timer/Counter 4 22 TC5 Timer/Counter 5 23 UHP USB Host Port 21 1768MS–ATARM–09-Jul-09 Table 10-1. 10.3 Peripheral Identifiers (Continued) Peripheral Peripheral Peripheral External ID Mnemonic Name Interrupt 24 EMAC Ethernet MAC 25 AIC Advanced Interrupt Controller IRQ0 26 AIC Advanced Interrupt Controller IRQ1 27 AIC Advanced Interrupt Controller IRQ2 28 AIC Advanced Interrupt Controller IRQ3 29 AIC Advanced Interrupt Controller IRQ4 30 AIC Advanced Interrupt Controller IRQ5 31 AIC Advanced Interrupt Controller IRQ6 Peripheral Multiplexing on PIO Lines The AT91RM9200 features four PIO controllers: • PIOA and PIOB, multiplexing I/O lines of the peripheral set • PIOC, multiplexing the data bus bits 16 to 31 and several External Bus Interface control signals. Using PIOC pins increases the number of general-purpose I/O lines available but prevents 32-bit memory access • PIOD, available in the 256-ball BGA package option only, multiplexing outputs of the peripheral set and the ETM port Each PIO Controller controls up to 32 lines. Each line can be assigned to one of two peripheral functions, A or B. The tables in the following paragraphs define how the I/O lines of the peripherals A and B are multiplexed on the PIO Controllers A, B, C and D. The two columns “Function” and “Comments” have been inserted for the user’s own comments; they may be used to track how pins are defined in an application. The column “Reset State” indicates whether the PIO line resets in I/O mode or in peripheral mode. If equal to “I/O”, 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 NRST pin is asserted. 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 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 for pins controlling memories, either address lines or chip selects, and that require the pin to be driven as soon as NRST raises. Note that the pull-up resistor is also enabled in this case. See Table 10-2 on page 23, Table 10-3 on page 24, Table 10-4 on page 25 and Table 10-5 on page 26. 22 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 10.3.1 PIO Controller A Multiplexing Table 10-2. Multiplexing on PIO Controller A PIO Controller A Application Usage Reset State I/O Line Peripheral A Peripheral B PA0 MISO PCK3 I/O PA1 MOSI PCK0 I/O PA2 SPCK IRQ4 I/O PA3 NPCS0 IRQ5 I/O PA4 NPCS1 PCK1 I/O PA5 NPCS2 TXD3 I/O PA6 NPCS3 RXD3 I/O PA7 ETXCK/EREFCK PCK2 I/O PA8 ETXEN MCCDB I/O PA9 ETX0 MCDB0 I/O PA10 ETX1 MCDB1 I/O PA11 ECRS/ECRSDV MCDB2 I/O PA12 ERX0 MCDB3 I/O PA13 ERX1 TCLK0 I/O PA14 ERXER TCLK1 I/O PA15 EMDC TCLK2 I/O PA16 EMDIO IRQ6 I/O PA17 TXD0 TIOA0 I/O PA18 RXD0 TIOB0 I/O PA19 SCK0 TIOA1 I/O PA20 CTS0 TIOB1 I/O PA21 RTS0 TIOA2 I/O PA22 RXD2 TIOB2 I/O PA23 TXD2 IRQ3 I/O PA24 SCK2 PCK1 I/O PA25 TWD IRQ2 I/O PA26 TWCK IRQ1 I/O PA27 MCCK TCLK3 I/O PA28 MCCDA TCLK4 I/O PA29 MCDA0 TCLK5 I/O PA30 DRXD CTS2 I/O PA31 DTXD RTS2 I/O Function Comments 23 1768MS–ATARM–09-Jul-09 10.3.2 PIO Controller B Multiplexing Table 10-3. Multiplexing on PIO Controller B PIO Controller B Application Usage I/O Line Peripheral A Peripheral B Reset State PB0 TF0 RTS3 I/O PB1 TK0 CTS3 I/O PB2 TD0 SCK3 I/O PB3 RD0 MCDA1 I/O PB4 RK0 MCDA2 I/O PB5 RF0 MCDA3 I/O PB6 TF1 TIOA3 I/O PB7 TK1 TIOB3 I/O PB8 TD1 TIOA4 I/O PB9 RD1 TIOB4 I/O PB10 RK1 TIOA5 I/O PB11 RF1 TIOB5 I/O PB12 TF2 ETX2 I/O PB13 TK2 ETX3 I/O PB14 TD2 ETXER I/O PB15 RD2 ERX2 I/O PB16 RK2 ERX3 I/O PB17 RF2 ERXDV I/O PB18 RI1 ECOL I/O PB19 DTR1 ERXCK I/O PB20 TXD1 I/O PB21 RXD1 I/O PB22 SCK1 I/O PB23 DCD1 I/O PB24 CTS1 I/O PB25 DSR1 PB26 RTS1 I/O PB27 PCK0 I/O PB28 FIQ I/O PB29 IRQ0 I/O 24 EF100 Function Comments I/O AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 10.3.3 PIO Controller C Multiplexing The PIO Controller C has no multiplexing and only peripheral A lines are used. Selecting Peripheral B on the PIO Controller C has no effect. Table 10-4. Multiplexing on PIO Controller C PIO Controller C I/O Line Peripheral A Peripheral B Application Usage Reset State PC0 BFCK I/O PC1 BFRDY/SMOE I/O PC2 BFAVD I/O PC3 BFBAA/SMWE I/O PC4 BFOE I/O PC5 BFWE I/O PC6 NWAIT I/O PC7 A23 A23 PC8 A24 A24 PC9 A25/CFRNW A25 PC10 NCS4/CFCS NCS4 PC11 NCS5/CFCE1 NCS5 PC12 NCS6/CFCE2 NCS6 PC13 NCS7 NCS7 PC14 I/O PC15 I/O PC16 D16 I/O PC17 D17 I/O PC18 D18 I/O PC19 D19 I/O PC20 D20 I/O PC21 D21 I/O PC22 D22 I/O PC23 D23 I/O PC24 D24 I/O PC25 D25 I/O PC26 D26 I/O PC27 D27 I/O PC28 D28 I/O PC29 D29 I/O PC30 D30 I/O PC31 D31 I/O Function Comments 25 1768MS–ATARM–09-Jul-09 10.3.4 PIO Controller D Multiplexing The PIO Controller D multiplexes pure output signals on peripheral A connections, in particular from the EMAC MII interface and the ETM Port on the peripheral B connections. The PIO Controller D is available only in the 256-ball BGA package option of the AT91RM9200. Table 10-5. Multiplexing on PIO Controller D PIO Controller D I/O Line 26 Peripheral A Application Usage Peripheral B Reset State PD0 ETX0 I/O PD1 ETX1 I/O PD2 ETX2 I/O PD3 ETX3 I/O PD4 ETXEN I/O PD5 ETXER I/O PD6 DTXD I/O PD7 PCK0 TSYNC I/O PD8 PCK1 TCLK I/O PD9 PCK2 TPS0 I/O PD10 PCK3 TPS1 I/O PD11 TPS2 I/O PD12 TPK0 I/O PD13 TPK1 I/O PD14 TPK2 I/O PD15 TD0 TPK3 I/O PD16 TD1 TPK4 I/O PD17 TD2 TPK5 I/O PD18 NPCS1 TPK6 I/O PD19 NPCS2 TPK7 I/O PD20 NPCS3 TPK8 I/O PD21 RTS0 TPK9 I/O PD22 RTS1 TPK10 I/O PD23 RTS2 TPK11 I/O PD24 RTS3 TPK12 I/O PD25 DTR1 TPK13 I/O PD26 TPK14 I/O PD27 TPK15 I/O Function Comments AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 10.3.5 System Interrupt The System Interrupt is the wired-OR of the interrupt signals coming from: • the Memory Controller • the Debug Unit • the System Timer • the Real-Time Clock • the Power Management Controller The clock of these peripherals cannot be controlled and the Peripheral ID 1 can only be used within the Advanced Interrupt Controller. 10.3.6 10.4 External Interrupts All external interrupt signals, i.e., the Fast Interrupt signal FIQ or the Interrupt signals IRQ0 to IRQ6, use a dedicated Peripheral ID. However, there is no clock control associated with these peripheral IDs. External Bus Interface • Integrates three External Memory Controllers: – Static Memory Controller – SDRAM Controller – Burst Flash Controller • Additional logic for NAND Flash/SmartMedia and CompactFlash support • Optimized External Bus: – 16- or 32-bit Data Bus – Up to 26-bit Address Bus, up to 64-Mbytes addressable – Up to 8 Chip Selects, each reserved to one of the eight Memory Areas – Optimized pin multiplexing to reduce latencies on External Memories • Configurable Chip Select Assignment: – Burst Flash Controller or Static Memory Controller on NCS0 – SDRAM Controller or Static Memory Controller on NCS1 – Static Memory Controller on NCS3, Optional NAND Flash/SmartMedia Support – Static Memory Controller on NCS4 - NCS6, Optional CompactFlash Support – Static Memory Controller on NCS7 10.5 Static Memory Controller • External memory mapping, 512-Mbyte address space • Up to 8 Chip Select Lines • 8- or 16-bit Data Bus • Remap of Boot Memory • Multiple Access Modes supported – Byte Write or Byte Select Lines – Two different Read Protocols for each Memory Bank • Multiple device adaptability 27 1768MS–ATARM–09-Jul-09 – Compliant with LCD Module – Programmable Setup Time Read/Write – Programmable Hold Time Read/Write • Multiple Wait State Management – Programmable Wait State Generation – External Wait Request – Programmable Data Float Time 10.6 SDRAM Controller • 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 and Low-power Modes supported • Error detection – Refresh Error Interrupt • SDRAM Power-up Initialization by software • Latency is set to two clocks (CAS Latency of 1, 3 Not Supported) • Auto Precharge Command not used 10.7 Burst Flash Controller • Multiple Access Modes supported – Asynchronous or Burst Mode Byte, Half-word or Word Read Accesses – Asynchronous Mode Half-word Write Accesses • Adaptability to different device speed grades – Programmable Burst Flash Clock Rate – Programmable Data Access Time – Programmable Latency after Output Enable • Adaptability to different device access protocols and bus interfaces – Two Burst Read Protocols: Clock Control Address Advance or Signal Controlled Address Advance – Multiplexed or separate address and data buses – Continuous Burst and Page Mode Accesses supported 28 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 10.8 Peripheral DMA Controller (PDC) • Generates transfers to/from peripherals such as DBGU, USART, SSC, SPI and MCI • Twenty channels • One Master Clock cycle needed for a transfer from memory to peripheral • Two Master Clock cycles needed for a transfer from peripheral to memory 10.9 System Timer • One Period Interval Timer, 16-bit programmable counter • One Watchdog Timer, 16-bit programmable counter • One Real-time Timer, 20-bit free-running counter • Interrupt Generation on event 10.10 Real-time Clock • Low power consumption • Full asynchronous design • Two hundred year calendar • Programmable Periodic Interrupt • Alarm and update parallel load • Control of alarm and update Time/Calendar Data In 10.11 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 USB devices • Root hub integrated with two downstream USB ports • Two embedded USB transceivers • Supports power management • Operates as a master on the Memory Controller 10.12 USB Device Port • USB V2.0 full-speed compliant, 12 Mbits per second • Embedded USB V2.0 full-speed transceiver • Embedded dual-port RAM for endpoints • Suspend/Resume logic • Ping-pong mode (two memory banks) for isochronous and bulk endpoints • Six general-purpose endpoints – Endpoint 0, Endpoint 3: 8 bytes, no ping-pong mode – Endpoint 1, Endpoint 2: 64 bytes, ping-pong mode – Endpoint 4, Endpoint 5: 256 bytes, ping-pong mode 10.13 Ethernet MAC • Compatibility with IEEE Standard 802.3 29 1768MS–ATARM–09-Jul-09 • 10 and 100 Mbits per second data throughput capability • Full- and half-duplex operation • MII or RMII interface to the physical layer • Register interface to address, status and control registers • DMA interface, operating as a master on the Memory Controller • Interrupt generation to signal receive and transmit completion • 28-byte transmit and 28-byte receive FIFOs • Automatic pad and CRC generation on transmitted frames • Address checking logic to recognize four 48-bit addresses • Supports promiscuous mode where all valid frames are copied to memory • Supports physical layer management through MDIO interface 10.14 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 • Connection to PDC channel optimizes data transfers – One channel for the receiver, one channel for the transmitter – Next buffer support 10.15 Two-wire Interface • Compatibility with standard two-wire serial memory • One, two or three bytes for slave address • Sequential Read/Write operations 10.16 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 30 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 – MSB- or LSB-first – Optional break generation and detection – By 8 or by-16 over-sampling receiver frequency – Optional hardware handshaking RTS-CTS – Optional modem signal management DTR-DSR-DCD-RI – Receiver time-out and transmitter timeguard – Optional Multi-drop Mode with address generation and detection • 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 • IrDA modulation and demodulation – Communication at up to 115.2 Kbps • Test Modes – Remote Loopback, Local Loopback, Automatic Echo • Connection of two Peripheral DMA Controller (PDC) channels – Offers buffer transfer without processor intervention The USART describes features allowing management of the Modem Signals DTR, DSR, DCD and RI. For details, see ”Modem Mode” on page 435. In the AT91RM9200, only the USART1 implements these signals, named DTR1, DSR1, DCD1 and RI1. The USART0, USART2 and USART3 do not implement all the modem signals. Only RTS and CTS (RTS0 and CTS0, RTS2 and CTS2, RTS3 and CTS3, respectively) are implemented in these USARTs for other features. Thus, programming the USART0, USART2 or the USART3 in Modem Mode may lead to unpredictable results. In these USARTs, the commands relating to the Modem Mode have no effect and the status bits relating the status of the modem signals are never activated. 10.17 Serial Synchronous Controller • Provides serial synchronous communication links used in audio and telecom applications • Contains an independent receiver and transmitter and a common clock divider • Interfaced with two PDC channels to reduce processor overhead • 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 10.18 Timer Counter • Three 16-bit Timer Counter Channels • Wide range of functions including: – Frequency Measurement – Event Counting 31 1768MS–ATARM–09-Jul-09 – 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 • Internal interrupt signal • Two global registers that act on all three TC Channels • The Timer Counter 0 to 5 are described with five generic clock inputs, TIMER_CLOCK1 to TIMER_CLOCK5. In the AT91RM9200, these clock inputs are connected to the Master Clock (MCK), to the Slow Clock (SLCK) and to divisions of the Master Clock. For details, see ”Clock Control” on page 488. Table 10-6 gives the correspondence between the Timer Counter clock inputs and clocks in the AT91RM9200. Each Timer Counter 0 to 5 displays the same configuration. Table 10-6. Timer Counter Clocks Assignment TC Clock Input Clock TIMER_CLOCK1 MCK/2 TIMER_CLOCK2 MCK/8 TIMER_CLOCK3 MCK/32 TIMER_CLOCK4 MCK/128 TIMER_CLOCK5 SLCK 10.19 MultiMedia Card Interface • Compatibility with MultiMedia Card Specification Version 2.2 • Compatibility with SD Memory Card Specification Version 1.0 • Cards clock rate up to Master Clock divided by 2 • Embedded power management to slow down clock rate when not used • Supports two slots – One slot for one MultiMedia Card bus (up to 30 cards) or one SD Memory Card • Support for stream, block and multi-block data read and write • Connection to a Peripheral DMA Controller (PDC) channel – Minimizes processor intervention for large buffer transfers 32 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 11. Package Drawings Figure 11-1. 208-lead PQFP Package Drawing C Table 11-1. C1 208-lead PQFP Package Dimensions (in mm) Symbol Min c 0.11 c1 0.11 L 0.65 L1 Nom Max Symbol Min Nom Max 0.23 b1 0.17 0.20 0.23 0.15 0.19 ddd 0.10 0.88 1.03 1.60 REF Tolerances of Form and Position aaa 0.3 0.25 R2 0.13 ccc 0.1 R1 0.13 S 0.4 D 31.20 A 4.10 D1 28.00 A1 0.25 0.50 E 31.20 A2 3.20 3.60 E1 28.00 b 0.17 0.27 e 0.50 BSC 3.40 33 1768MS–ATARM–09-Jul-09 Figure 11-2. 256-ball BGA Package Drawing 34 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 12. AT91RM9200 Ordering Information Table 12-1. Ordering Information Ordering Code Package Package Type Temperature Operating Range AT91RM9200-QU-002 PQFP 208 Green AT91RM9200-CJ-002 BGA 256 RoHS-compliant Industrial (-40⋅ C to 85⋅ C) 35 1768MS–ATARM–09-Jul-09 13. Revision History Doc. Rev Source Comments Lit°1768A • Date Qualified: May 2001 Lit°1768B • Date Qualified: September 2001 Lit°1768C • Date Qualified: November 2001 Lit°1768D • Date Qualified: 5 Mar-02 Lit°1768E • Date Qualified: 12-Jul-02 Lit°1768F • Date Qualified: 5 Feb-03 Doc. Rev Source Comments 1768GS Review • Date Qualified: 04-Sep-03 • Page 2; Added Description. • Page 3; Updated Figure 1, Block Diagram, remove reference to Multi-master Memory Controller. • Page 4; Added section Key Features. Updated all descriptions of key blocks • Page 17; Added text to section Peripheral Multiplexing on PIO Lines. • Page 18; Expanded Table 3, Multiplexing on PIO Controller A. • Page 19: Expanded Table 4, Multiplexing on PIO Controller B. • Page 20; Expanded Table 5, Multiplexing on PIO Controller C. • Page 21; Expanded Table 6, Multiplexing on PIO Controller D. • Page 27; Updated Table 8, Peripheral Identifiers, Peripheral ID 1 description. • Page 28; Added section Product Memory Mapping. • Page 30; Updated and corrected Figure 6, System Peripherals Mapping. • Page 31; Updated and corrected Figure 7, User Peripherals Mapping. Doc. Rev Source Comments 1768HS CSRs/Review • Date Qualified: Unqualified/Internal on Intranet 27-Jan-05 • Global; Reformat in Corporate Template. • Global; Peripheral Data Controller (PDC) renamed Peripheral DMA Controller. Doc. Rev CSR 04-066 • Page 1; Features: USART Hardware Handshaking. Software Handshaking removed. CSR 03-209 • Page 3; Figure 1: NWAIT pin added to block diagram. CSR 03-244 • Page 14; Table 1. AT91RM9200 Pinout for 208-lead PQFP package, pins 28, 30, 37 and 39 names changed CSR 04-315 • Page 23; Table 7. Pin Description, ICE and JTAG description, “Internal Pullup” added to comments for all signals, except TDO. CSR 03-209 • Page 24; Table 7. Pin Description, NWAIT pin added. Source Comments Corrected power consumption values on page 1. 1768IS 36 CSR 05-348 In Table 4-7, “Pin Description List,” on page 24 added mention of Schmitt trigger for pins JTAGSEL, TDI, TCK, TMS, NTRST, TST0, TST1 and NRST. AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 Revision History (cont.) Document Ref. Comments 1768JS Reformatted Section 8. ”Memories” on page 17. Inserted new figure Figure 8-1 on page 17 with overall product memory map. Change Request Ref. Added Section 11. “Package Drawings” on page 33. 1768KS Updated “Features” and Section 4. ”Package and Pinout” on page 8 with additional details on package options. Updated Table 40-1, “Ordering Information,” on page 661. 1768LS Ordering code AT91RM9200-CI-002 removed from Section 12. “AT91RM9200 Ordering Information” on page 35 6423 1768MS USART3 0XFFECC000 changed into 0XFFFCC000 in Figure 8-1 on page 17 5067 37 1768MS–ATARM–09-Jul-09 38 AT91RM9200 1768MS–ATARM–09-Jul-09 AT91RM9200 39 1768MS–ATARM–09-Jul-09 40 AT91RM9200 1768MS–ATARM–09-Jul-09 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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