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| EP7311 Data Sheet FEATURES ARM720T Processor -- ARM7TDMI CPU -- 8 KB of four-way set-associative cache -- MMU with 64-entry TLB -- Thumb code support enabled Ultra low power -- 90 mW at 74 MHz typical -- 30 mW at 18 MHz typical -- 10 mW in the Idle State -- <1 mW in the Standby State 48 KB of on-chip SRAM MaverickKeyTM IDs -- 32-bit unique ID can be used for SDMI compliance -- 128-bit random ID Dynamically programmable clock speeds of 18, 36, 49, and 74 MHz High-performance, Low-power, System-on-chip with SDRAM & Enhanced Digital Audio Interface OVERVIEW The MaverickTM EP7311 is designed for ultra-low-power applications such as PDAs, smart cellular phones, and industrial hand held information appliances. The core-logic functionality of the device is built around an ARM720T processor with 8 KB of four-way set-associative unified cache and a write buffer. Incorporated into the ARM720T is an enhanced memory management unit (MMU) which allows for support of sophisticated operating systems like Linux(R). (cont.) (cont.) BLOCK DIAGRAM Multimedia Codec Port Power Management EPB Bus Clocks & Timers ARM720T USER INTERFACE ICE-JTAG ARM7TDMI CPU Core Interrupts, PWM & GPIO SERIAL PORTS Serial Interface (2) UARTs w/ IrDA Internal Data Bus 8 KB Cache Boot ROM Write Buffer Bus Bridge MMU Keypad& Touch Screen I/F Memory Controller TM MaverickKey SRAM I/F SDRAM I/F On-chip SRAM 48 KB LCD Controller MEMORY AND STORAGE (c)Copyright Cirrus Logic, Inc. 2005 http://www.cirrus.com (All Rights Reserved) AUG `05 DS506F1 EP7311 High-Performance, Low-Power System on Chip FEATURES (cont) LCD controller -- Interfaces directly to a single-scan panel monochrome STN LCD -- Interfaces to a single-scan panel color STN LCD with minimal external glue logic Full JTAG boundary scan and Embedded ICE(R) support Integrated Peripheral Interfaces -- 32-bit SDRAM Interface up to 2 external banks -- 8/32/16-bit SRAM/FLASH/ROM Interface -- Multimedia Codec Port -- Two Synchronous Serial Interfaces (SSI1, SSI2) -- CODEC Sound Interface -- 8x8 Keypad Scanner -- 27 General Purpose Input/Output pins -- Dedicated LED flasher pin from the RTC Internal Peripherals -- Two 16550 compatible UARTs -- IrDA Interface -- Two PWM Interfaces -- Real-time Clock -- Two general purpose 16-bit timers -- Interrupt Controller -- Boot ROM Package -- 208-Pin LQFP -- 256-Ball PBGA -- 204-Ball TFBGA The fully static EP7311 is optimized for low power dissipation and is fabricated on a 0.25 micron CMOS process Development Kits -- EDB7312: Development Kit with color STN LCD on board. -- EDB7312-LW: EDB7312 with Lynuxworks' BlueCat Linux Tools and software for Windows host (free 30 day BlueCat support from Lynuxworks). -- EDB7312-LL: EDB7312 with Lynuxworks' BlueCat Linux Tools and software for Linux host (free 30 day BlueCat support from Lynuxworks). Note: * BlueCat available separately through Lynuxworks only. * Use the EDB7312 Development Kit for all the EP73xx devices. OVERVIEW (cont.) The EP7311 is designed for low-power operation. Its core operates at only 2.5 V, while its I/O has an operation range of 2.5 V-3.3 V. The device has three basic power states: operating, idle and standby. One of its notable features is MaverickKey unique IDs. These are factory programmed IDs in response to the growing concern over secure web content and commerce. With Internet security playing an important role in the delivery of digital media such as books or music, traditional software methods are quickly becoming unreliable. The MaverickKey unique IDs consist of two registers, one 32-bit series register and one random 128-bit register that may be used by an OEM for an authentication mechanism. Simply by adding desired memory and peripherals to the highly integrated EP7311 completes a low-power system solution. All necessary interface logic is integrated on-chip. 2 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Table of Contents FEATURES...................................................................................................................................................................1 OVERVIEW ..................................................................................................................................................................1 Processor Core - ARM720T ..................................................................................................................................6 Power Management ..............................................................................................................................................6 MaverickKeyTM Unique ID ......................................................................................................................................6 Memory Interfaces .................................................................................................................................................6 Digital Audio Capability .........................................................................................................................................6 Universal Asynchronous Receiver/Transmitters (UARTs) .....................................................................................6 Digital Audio Interface (DAI) ..................................................................................................................................7 CODEC Interface ..................................................................................................................................................7 SSI2 Interface ........................................................................................................................................................7 Synchronous Serial Interface ................................................................................................................................8 LCD Controller .......................................................................................................................................................8 Interrupt Controller ................................................................................................................................................8 Real-Time Clock ....................................................................................................................................................8 PLL and Clocking ..................................................................................................................................................9 DC-to-DC converter interface (PWM) ....................................................................................................................9 Timers ...................................................................................................................................................................9 General Purpose Input/Output (GPIO) ..................................................................................................................9 Hardware debug Interface .....................................................................................................................................9 Internal Boot ROM ...............................................................................................................................................10 Packaging ............................................................................................................................................................10 Pin Multiplexing ...................................................................................................................................................10 System Design ....................................................................................................................................................11 ELECTRICAL SPECIFICATIONS ......................................................................................................12 Absolute Maximum Ratings .................................................................................................................................12 Recommended Operating Conditions .................................................................................................................12 DC Characteristics ..............................................................................................................................................12 Timings ...............................................................................................................................................14 Timing Diagram Conventions ....................................................................................................................14 Timing Conditions ......................................................................................................................................14 Static Memory .....................................................................................................................................................15 Static Memory Single Read Cycle .............................................................................................................16 Static Memory Single Write Cycle .............................................................................................................17 Static Memory Burst Read Cycle ...............................................................................................................18 Static Memory Burst Write Cycle ...............................................................................................................19 SSI1 Interface ......................................................................................................................................................20 SSI2 Interface ......................................................................................................................................................21 LCD Interface ......................................................................................................................................................22 JTAG Interface .....................................................................................................................................................23 Packages ............................................................................................................................................24 208-Pin LQFP Package Characteristics ..............................................................................................................24 208-Pin LQFP Package Specifications ......................................................................................................24 208-Pin LQFP Pin Diagram .......................................................................................................................25 208-Pin LQFP Numeric Pin Listing ............................................................................................................26 204-Ball TFBGA Package Characteristics ...........................................................................................................29 204-Ball TFBGA Package Specifications ..................................................................................................29 204-Ball TFBGA Pinout (Top View) ...........................................................................................................30 DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 3 EP7311 High-Performance, Low-Power System on Chip 204-Ball TFBGA Ball Listing ...................................................................................................................... 31 256-Ball PBGA Package Characteristics ............................................................................................................ 38 256-Ball PBGA Package Specifications .................................................................................................... 38 256-Ball PBGA Pinout (Top View)) ............................................................................................................ 39 256-Ball PBGA Ball Listing ........................................................................................................................ 39 JTAG Boundary Scan Signal Ordering ............................................................................................................... 43 CONVENTIONS ................................................................................................................................. 48 Acronyms and Abbreviations .............................................................................................................................. 48 Units of Measurement ......................................................................................................................................... 48 General Conventions .......................................................................................................................................... 49 Pin Description Conventions ............................................................................................................................... 49 49 Ordering Information ....................................................................................................................... 50 Environmental, Manufacturing, & Handling Information .............................................................. 50 Revision History ............................................................................................................................... 51 4 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip List of Figures Figure 1. A Maximum EP7309 Based System ..............................................................................................................11 Figure 2. Legend for Timing Diagrams .........................................................................................................................14 Figure 3. Static Memory Single Read Cycle Timing Measurement ...............................................................................16 Figure 4. Static Memory Single Write Cycle Timing Measurement ...............................................................................17 Figure 5. Static Memory Burst Read Cycle Timing Measurement ................................................................................18 Figure 6. Static Memory Burst Write Cycle Timing Measurement ................................................................................19 Figure 7. SSI1 Interface Timing Measurement .............................................................................................................20 Figure 8. SSI2 Interface Timing Measurement .............................................................................................................21 Figure 9. LCD Controller Timing Measurement ............................................................................................................22 Figure 10. JTAG Timing Measurement .........................................................................................................................23 Figure 11. 208-Pin LQFP Package Outline Drawing ....................................................................................................24 Figure 12. 208-Pin LQFP (Low Profile Quad Flat Pack) Pin Diagram ..........................................................................25 Figure 13. 204-Ball TFBGA Package ............................................................................................................................29 Figure 14. 256-Ball PBGA Package ..............................................................................................................................38 List of Tables Table 1. Power Management Pin Assignments ..............................................................................................................6 Table 2. Static Memory Interface Pin Assignments ........................................................................................................6 Table 3. Universal Asynchronous Receiver/Transmitters Pin Assignments ...................................................................7 Table 4. DAI Interface Pin Assignments .........................................................................................................................7 Table 5. CODEC Interface Pin Assignments ..................................................................................................................7 Table 6. SSI2 Interface Pin Assignments .......................................................................................................................7 Table 7. Serial Interface Pin Assignments ......................................................................................................................8 Table 8. LCD Interface Pin Assignments ........................................................................................................................8 Table 9. Keypad Interface Pin Assignments ...................................................................................................................8 Table 10. Interrupt Controller Pin Assignments ..............................................................................................................8 Table 11. Real-Time Clock Pin Assignments ..................................................................................................................9 Table 12. PLL and Clocking Pin Assignments ................................................................................................................9 Table 13. DC-to-DC Converter Interface Pin Assignments .............................................................................................9 Table 14. General Purpose Input/Output Pin Assignments ............................................................................................9 Table 15. Hardware Debug Interface Pin Assignments ..................................................................................................9 Table 16. LED Flasher Pin Assignments ........................................................................................................................9 Table 17. DAI/SSI2/CODEC Pin Multiplexing ...............................................................................................................10 Table 18. Pin Multiplexing .............................................................................................................................................10 Table 19. 208-Pin LQFP Numeric Pin Listing ...............................................................................................................26 Table 20. 204-Ball TFBGA Ball Listing .........................................................................................................................31 Table 21. 256-Ball PBGA Ball Listing ...........................................................................................................................39 Table 22. JTAG Boundary Scan Signal Ordering .........................................................................................................43 Table 23. Acronyms and Abbreviations ........................................................................................................................48 Table 24. Unit of Measurement .....................................................................................................................................48 Table 25. Pin Description Conventions .........................................................................................................................49 DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 5 EP7311 High-Performance, Low-Power System on Chip Processor Core - ARM720T The EP7311 incorporates an ARM 32-bit RISC microcontroller that controls a wide range of on-chip peripherals. The processor utilizes a three-stage pipeline consisting of fetch, decode and execute stages. Key features include: * * * * ARM (32-bit) and Thumb (16-bit compressed) instruction sets Enhanced MMU for Microsoft Windows CE and other operating systems 8 KB of 4-way set-associative cache. Translation Look Aside Buffers with 64 Translated Entries Both a specific 32-bit ID as well as a 128-bit random ID is programmed into the EP7311 through the use of laser probing technology. These IDs can then be used to match secure copyrighted content with the ID of the target device the EP7311 is powering, and then deliver the copyrighted information over a secure connection. In addition, secure transactions can benefit by also matching device IDs to server IDs. MaverickKey IDs provide a level of hardware security required for today's Internet appliances. Memory Interfaces There are two main external memory interfaces. The first one is the ROM/SRAM/FLASH-style interface that has programmable wait-state timings and includes burst-mode capability, with six chip selects decoding six 256 MB sections of addressable space. For maximum flexibility, each bank can be specified to be 8-, 16-, or 32-bits wide. This allows the use of 8-bit-wide boot ROM options to minimize overall system cost. The on-chip boot ROM can be used in product manufacturing to serially download system code into system FLASH memory. To further minimize system memory requirements and cost, the ARM Thumb instruction set is supported, providing for the use of high-speed 32-bit operations in 16-bit op-codes and yielding industry-leading code density. Pin Mnemonic nCS[5:0] A[27:0] D[31:0] nMOE/nSDCAS (Note) (Note) Power Management The EP7311 is designed for ultra-low-power operation. Its core operates at only 2.5 V, while its I/O has an operation range of 2.5 V-3.3 V allowing the device to achieve a performance level equivalent to 60 MIPS. The device has three basic power states: * Operating -- This state is the full performance state. All the clocks and peripheral logic are enabled. * Idle -- This state is the same as the Operating State, except the CPU clock is halted while waiting for an event such as a key press. * Standby -- This state is equivalent to the computer being switched off (no display), and the main oscillator shut down. An event such as a key press can wake-up the processor. I/O O O I/O O O O O Pin Description Chip select out Address output Data I/O ROM expansion OP enable ROM expansion write enable Halfword access select output Word access select output Transfer direction Pin Mnemonic BATOK nEXTPWR nPWRFL nBATCHG I/O I I I I Pin Description Battery ok input External power supply sense input Power fail sense input Battery changed sense input nMWE/nSDWE HALFWORD WORD WRITE/nSDRAS (Note) O Table B. Static Memory Interface Pin Assignments Note: Pins are multiplexed. See Table S on page 11 for more information. Table A. Power Management Pin Assignments MaverickKeyTM Unique ID MaverickKey unique hardware programmed IDs are a solution to the growing concern over secure web content and commerce. With Internet security playing an important role in the delivery of digital media such as books or music, traditional software methods are quickly becoming unreliable. The MaverickKey unique IDs provide OEMs with a method of utilizing specific hardware IDs such as those assigned for SDMI (Secure Digital Music Initiative) or any other authentication mechanism. (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 6 EP7311 High-Performance, Low-Power System on Chip The second is the programmable 16- or 32-bit-wide SDRAM interface that allows direct connection of up to two banks of SDRAM, totaling 512 Mb. To assure the lowest possible power consumption, the EP7311 supports self-refresh SDRAMs, which are placed in a low-power state by the device when it enters the low-power Standby State. Pin Mnemonic SDCLK SDCKE nSDCS[1:0] WRITE/nSDRAS nMOE/nSDCAS nMWE/nSDWE A[27:15]/DRA[0:12] A[14:13]/DRA[12:14] PD[7:6]/SDQM[1:0] SDQM[3:2] D[31:0] (Note 2) (Note 2) (Note 2) (Note 2) (Note 1) UART 1 to enable these signals to drive an infrared communication interface directly. Pin Mnemonic TXD[1] RXD[1] I/O O I I I I O I O I Pin Description UART 1 transmit UART 1 receive UART 1 clear to send UART 1 data carrier detect UART 1 data set ready UART 2 transmit UART 2 receive Infrared LED drive output Photo diode input I/O O O O O O O O O I/O O I/O Pin Description SDRAM clock output SDRAM clock enable output SDRAM chip select out SDRAM RAS signal output SDRAM CAS control signal SDRAM write enable control signal SDRAM address SDRAM internal bank select SDRAM byte lane mask SDRAM byte lane mask Data I/O CTS DCD DSR TXD[2] RXD[2] LEDDRV PHDIN Table D. Universal Asynchronous Receiver/Transmitters Pin Assignments Multimedia Codec Port (MCP) The Multimedia Codec Port provides access to an audio codec, a telecom codec, a touchscreen interface, four general purpose analog-to-digital converter inputs, and ten programmable digital I/O lines. Pin Mnemonic SIBCLK SIBDOUT SIBDIN Table C. SDRAM Interface Pin Assignments Note: 1. Pins A[27:13] map to DRA[0:14] respectively. (i.e. A[27}/DRA[0}, A[26}/DRA[1], etc.) This is to balance the load for large memory systems. 2. Pins are multiplexed. See Table S on page 11 for more information. I/O O O I O Pin Description Serial bit clock Serial data out Serial data in Sample clock Digital Audio Capability The EP7311 uses its powerful 32-bit RISC processing engine to implement audio decompression algorithms in software. The nature of the on-board RISC processor, and the availability of efficient C-compilers and other software development tools, ensures that a wide range of audio decompression algorithms can easily be ported to and run on the EP7311 SIBSYNC Table E. MCP Interface Pin Assignments Note: See Table R on page 11 for information on pin multiplexes. Universal Asynchronous Receiver/Transmitters (UARTs) The EP7311 includes two 16550-type UARTs for RS-232 serial communications, both of which have two 16-byte FIFOs for receiving and transmitting data. The UARTs support bit rates up to 115.2 kbps. An IrDA SIR protocol encoder/decoder can be optionally switched into the RX/TX signals to/from DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 7 EP7311 High-Performance, Low-Power System on Chip CODEC Interface The EP7311 includes an interface to telephony-type CODECs for easy integration into voice-over-IP and other voice communications systems. The CODEC interface is multiplexed to the same pins as the MCP and SSI2. Pin Mnemonic PCMCLK PCMOUT PCMIN PCMSYNC Synchronous Serial Interface * * ADC (SSI) Interface: Master mode only; SPI and Microwire1-compatible (128 kbps operation) Selectable serial clock polarity I/O O O I O Pin Description Serial bit clock Serial data out Serial data in Frame sync Pin Mnemonic ADCLK ADCIN ADCOUT nADCCS SMPCLK I/O O I O O O Pin Description SSI1 ADC serial clock SSI1 ADC serial input SSI1 ADC serial output SSI1 ADC chip select SSI1 ADC sample clock Table F. CODEC Interface Pin Assignments Note: See Table R on page 11 for information on pin multiplexes. Table H. Serial Interface Pin Assignments LCD Controller SSI2 Interface An additional SPI/Microwire1-compatible interface is available for both master and slave mode communications. The SSI2 unit shares the same pins as the MCP and CODEC interfaces through a multiplexer. * * * * Synchronous clock speeds of up to 512 kHz Separate 16 entry TX and RX half-word wide FIFOs Half empty/full interrupts for FIFOs Separate RX and TX frame sync signals for asymmetric traffic A DMA address generator is provided that fetches video display data for the LCD controller from memory. The display frame buffer start address is programmable, allowing the LCD frame buffer to be in SDRAM, internal SRAM or external SRAM. * * * * Pin Mnemonic SSICLK SSITXDA SSIRXDA SSITXFR SSIRXFR I/O I/O O I I/O I/O Pin Description Serial bit clock Serial data out Serial data in Transmit frame sync Receive frame sync * Interfaces directly to a single-scan panel monochrome STN LCD Interfaces to a single-scan panel color STN LCD with minimal external glue logic Panel width size is programmable from 32 to 1024 pixels in 16-pixel increments Video frame buffer size programmable up to 128 KB Bits per pixel of 1, 2, or 4 bits Pin Mnemonic CL1 CL2 DD[3:0] FRM M I/O O O O O O Pin Description LCD line clock LCD pixel clock out LCD serial display data bus LCD frame synchronization pulse LCD AC bias drive Table G. SSI2 Interface Pin Assignments Note: See Table R on page 11 for information on pin multiplexes. Table I. LCD Interface Pin Assignments 8 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip 64-Keypad Interface Matrix keyboards and keypads can be easily read by the EP7311. A dedicated 8-bit column driver output generates strobes for each keyboard column signal. The pins of Port A, when configured as inputs, can be selectively OR'ed together to provide a keyboard interrupt that is capable of waking the system from a STANDBY or IDLE state. * * * * * Column outputs can be individually set high with the remaining bits left at high-impedance Column outputs can be driven all-low, all-high, or all-highimpedance Keyboard interrupt driven by OR'ing together all Port A bits Keyboard interrupt can be used to wake up the system 8x8 keyboard matrix usable with no external logic, extra keys can be added with minimal glue logic . Pin Mnemonic nEINT[2:1] EINT[3] nEXTFIQ nMEDCHG/nBROM (Note) I/O I I I I Pin Description External interrupt External interrupt External Fast Interrupt input Media change interrupt input Table K. Interrupt Controller Pin Assignments Note: Pins are multiplexed. See Table S on page 11 for more information. Real-Time Clock The EP7311 contains a 32-bit Real Time Clock (RTC) that can be written to and read from in the same manner as the timer counters. It also contains a 32-bit output match register which can be programmed to generate an interrupt. * Driven by an external 32.768 kHz crystal oscillator Pin Mnemonic COL[7:0] I/O O Pin Description Keyboard scanner column drive Pin Mnemonic RTCIN RTCOUT VDDRTC VSSRTC Pin Description Real-Time Clock Oscillator Input Real-Time Clock Oscillator Output Real-Time Clock Oscillator Power Real-Time Clock Oscillator Ground Table J. Keypad Interface Pin Assignments Interrupt Controller When unexpected events arise during the execution of a program (i.e., interrupt or memory fault) an exception is usually generated. When these exceptions occur at the same time, a fixed priority system determines the order in which they are handled. The EP7311 interrupt controller has two interrupt types: interrupt request (IRQ) and fast interrupt request (FIQ). The interrupt controller has the ability to control interrupts from 22 different FIQ and IRQ sources. * * * Supports 22 interrupts from a variety of sources (such as UARTs, SSI1, and key matrix.) Routes interrupt sources to the ARM720T's IRQ or FIQ (Fast IRQ) inputs Five dedicated off-chip interrupt lines operate as level sensitive interrupts Table L. Real-Time Clock Pin Assignments PLL and Clocking * * Processor and Peripheral Clocks operate from a single 3.6864 MHz crystal or external 13 MHz clock Programmable clock speeds allow the peripheral bus to run at 18 MHz when the processor is set to 18 MHz and at 36 MHz when the processor is set to 36, 49 or 74 MHz Pin Mnemonic MOSCIN MOSCOUT VDDOSC VSSOSC Pin Description Main Oscillator Input Main Oscillator Output Main Oscillator Power Main Oscillator Ground Table M. PLL and Clocking Pin Assignments DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 9 EP7311 High-Performance, Low-Power System on Chip DC-to-DC converter interface (PWM) * Provides two 96 kHz clock outputs with programmable duty ratio (from 1-in-16 to 15-in-16) that can be used to drive a positive or negative DC to DC converter Hardware debug Interface * Full JTAG boundary scan and Embedded ICE(R) support Pin Mnemonic Pin Mnemonic DRIVE[1:0] FB[1:0] I/O I I O I I Pin Description JTAG clock JTAG data input JTAG data output JTAG async reset input JTAG mode select I/O I/O I Pin Description PWM drive output PWM feedback input TCLK TDI TDO nTRST TMS Table N. DC-to-DC Converter Interface Pin Assignments Timers * * Internal (RTC) timer Two internal 16-bit programmable hardware count-down timers Table P. Hardware Debug Interface Pin Assignments LED Flasher A dedicated LED flasher module can be used to generate a low frequency signal on Port D pin 0 for the purpose of blinking an LED without CPU intervention. The LED flasher feature is ideal as a visual annunciator in battery powered applications, such as a voice mail indicator on a portable phone or an appointment reminder on a PDA. * * * * Software adjustable flash period and duty cycle Operates from 32 kHz RTC clock Will continue to flash in IDLE and STANDBY states 4 mA drive current General Purpose Input/Output (GPIO) * * Three 8-bit and one 3-bit GPIO ports Supports scanning keyboard matrix Pin Mnemonic PA[7:0] PB[7:0] PD[0]/LEDFLSH PD[5:1] PD[7:6]/SDQM[1:0] (Note) (Note) I/O I/O I/O I/O I/O I/O I/O I/O Pin Description GPIO port A GPIO port B GPIO port D GPIO port D GPIO port D GPIO port E GPIO port E Pin Mnemonic PD[0]/LEDFLSH (Note) I/O O Pin Description LED flasher driver PE[1:0]/BOOTSEL[1:0] (Note) PE[2]/CLKSEL (Note) Table Q. LED Flasher Pin Assignments Note: Pins are multiplexed. See Table S on page 11 for more information. Table O. General Purpose Input/Output Pin Assignments Note: Pins are multiplexed. See Table S on page 11 for more information. Internal Boot ROM The internal 128 byte Boot ROM facilitates download of saved code to the on-board SRAM/FLASH. Packaging The EP7311 is available in a 208-pin LQFP package, 256-ball PBGA package or a 204-ball TFBGA package. 10 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Pin Multiplexing The following table shows the pin multiplexing of the MCP, SSI2 and the CODEC. The selection between SSI2 and the CODEC is controlled by the state of the SERSEL bit in SYSCON2. The choice between the SSI2, CODEC, and the MCP is controlled by the MCPSEL bit in SYSCON3 (see the EP73xx User's Manual for more information). Pin Mnemonic SSICLK SSITXDA SSIRXDA SSITXFR SSIRXFR BUZ The following table shows the pins that have been multiplexed in the EP7311. Signal nMOE nMWE WRITE A[27:15] A[14:13] Block Static Memory Static Memory Static Memory Static Memory Static Memory GPIO System Configuration Interrupt Controller GPIO GPIO GPIO Signal nSDCAS nSDWE nSDRAS DRA[0:12] DRA[13:14] SDQM[1:0] CLKEN nBROM LEDFLSH BOOTSEL[1:0] CLKSEL Block SDRAM SDRAM SDRAM SDRAM SDRAM SDRAM System Configuration Boot ROM select LED Flasher System Configuration System Configuration I/O I/O O I I/O I O MCP SIBCLK SIBDOUT SIBDIN SIBSYNC p/u SSI2 SSICLK SSITXDA SSIRXDA SSITXFR SSIRXFR CODEC PCMCLK PCMOUT PCMIN PCMSYNC p/u PD[7:6] RUN nMEDCHG PD[0] PE[1:0] Table R. MCP/SSI2/CODEC Pin Multiplexing PE[2] Table S. Pin Multiplexing DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 11 EP7311 High-Performance, Low-Power System on Chip System Design As shown in system block diagram, simply adding desired memory and peripherals to the highly integrated EP7311 completes a low-power system solution. All necessary interface logic is integrated on-chip. CRYSTAL CRYSTAL MOSCIN RTCIN nCS[4] PB0 EXPCLK D[0-31] DD[0-3] CL1 CL2 FRM M COL[0-7] LCD PC CARD SOCKET PC CARD CONTROLLER PA[0-7] PB[0-7] PD[0-7] PE[0-2] KEYBOARD A[0-27] nMOE WRITE SDCAS x16 SDRAM x16 SDRAM x16 SDRAM x16 SDRAM SDCS[0] SDQM[0-3] SDCS[1] SDQM[0-3] EP7311 SDRAS/ nPOR nPWRFL BATOK nEXTPWR nBATCHG RUN WAKEUP DRIVE[0-1] FB[0-1] POWER SUPPLY UNIT AND COMPARATORS DC INPUT BATTERY DC-TO-DC CONVERTERS CODEC/SSI2/ MCP nCS[0] nCS[1] x16 FLASH x16 FLASH x16 FLASH x16 FLASH CS[n] WORD SSICLK SSITXFR SSITXDA SSIRXDA SSIRXFR LEDDRV PHDIN RXD1/2 TXD1/2 DSR CTS DCD ADCCLK nADCCS ADCOUT ADCIN SMPCLK IR LED AND PHOTODIODE EXTERNAL MEMORYMAPPED EXPANSION BUFFERS nCS[2] nCS[3] 2x RS-232 TRANSCEIVERS ADDITIONAL I/O BUFFERS AND LATCHES ADC DIGITIZER LEDFLSH Figure 1. A Maximum EP7311 Based System Note: A system can only use one of the following peripheral interfaces at any given time: SSI2,CODEC or MCP. 12 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip ELECTRICAL SPECIFICATIONS Absolute Maximum Ratings DC Core, PLL, and RTC Supply Voltage DC I/O Supply Voltage (Pad Ring) DC Pad Input Current Storage Temperature, No Power 2.9 V 3.6 V 10 mA/pin; 100 mA cumulative -40C to +125C Recommended Operating Conditions DC core, PLL, and RTC Supply Voltage DC I/O Supply Voltage (Pad Ring) DC Input / Output Voltage Operating Temperature 2.5 V 0.2 V 2.3 V - 3.5 V O-I/O supply voltage Extended -20C to +70C; Commercial 0C to +70C; Industrial -40C to +85C DC Characteristics All characteristics are specified at VDDCORE = 2.5 V, VDDIO = 3.3 V and VSS = 0 V over an operating temperature of 0C to +70C for all frequencies of operation. The current consumption figures have test conditions specified per parameter." Symbol VIH VIL VT+ Parameter CMOS input high voltage CMOS input low voltage Schmitt trigger positive going threshold Schmitt trigger negative going threshold Schmitt trigger hysteresis CMOS output high voltagea Min 0.65 x VDDIO VSS - 0.3 - Typ - Max VDDIO + 0.3 0.25 x VDDIO 2.1 Unit V V V Conditions VDDIO = 2.5 V VDDIO = 2.5 V VTVhst 0.8 0.1 VDD - 0.2 2.5 2.5 25 8 8 - 0.4 0.3 0.5 0.5 1.0 100 10.0 10.0 V V V V V V V V A A pF pF VIL to VIH IOH = 0.1 mA IOH = 4 mA IOH = 12 mA IOL = -0.1 mA IOL = -4 mA IOL = -12 mA VIN = VDD or GND VOUT = VDD or GND VOH Output drive 1a Output drive 2a CMOS output low voltagea VOL Output drive 1a Output drive 2a IIN IOZ CIN COUT Input leakage current Bidirectional 3-state leakage currentb c Input capacitance Output capacitance DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 13 EP7311 High-Performance, Low-Power System on Chip Symbol CI/O Parameter Transceiver capacitance Min 8 Typ - Max 10.0 Unit pF Conditions IDDSTANDBY @ 25 C Standby current consumption1 Core, Osc, RTC @2.5 V I/O @ 3.3 V - 77 41 - A Only nPOR, nPWRFAIL, nURESET, PE0, PE1, and RTS are driven, while all other float, VIH = VDD 0.1 V, VIL = GND 0.1 V Only nPOR, nPWRFAIL, nURESET, PE0, PE1, and RTS are driven, while all other float, VIH = VDD 0.1 V, VIL = GND 0.1 V Only nPOR, nPWRFAIL, nURESET, PE0, PE1, and RTS are driven, while all other float, VIH = VDD 0.1 V, VIL = GND 0.1 V Both oscillators running, CPU static, Cache enabled, LCD disabled, VIH = VDD 0.1 V, VIL = GND 0.1 V Minimum standby voltage for state retention, internal SRAM cache, and RTC operation only IDDSTANDBY @ 70 C Standby current consumption1 Core, Osc, RTC @2.5 V I/O @ 3.3 V - - 570 111 A IDDSTANDBY @ 85 C Standby current consumption1 Core, Osc, RTC @2.5 V I/O @ 3.3 V 1693 163 A IDDidle at 74 MHz Idle current consumption1 Core, Osc, RTC @2.5 V I/O @ 3.3 V - 6 10 - mA VDDSTANDBY Standby supply voltage a. b. c. Note: 2.0 - - V Refer to the strength column in the pin assignment tables for all package types. Assumes buffer has no pull-up or pull-down resistors. The leakage value given assumes that the pin is configured as an input pin but is not currently being driven. 1) Total power consumption = IDDCORE x 2.5 V + IDDIO x 3.3 V 2) A typical design will provide 3.3 V to the I/O supply (i.e., VDDIO), and 2.5 V to the remaining logic. This is to allow the I/O to be compatible with 3.3 V powered external logic (i.e., 3.3 V SDRAMs). 2) Pull-up current = 50 A typical at VDD = 3.3 V. 14 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Timings Timing Diagram Conventions This data sheet contains timing diagrams. The following key explains the components used in these diagrams. Any variations are clearly labelled when they occur. Therefore, no additional meaning should be attached unless specifically stated. C lo c k H ig h to Low H ig h / L o w to H ig h Bus C hange Bus V a lid U n d e f in e d / I n v a lid V a lid B u s to T r is ta te B u s / S ig n a l O m is s io n Figure 2. Legend for Timing Diagrams Timing Conditions Unless specified otherwise, the following conditions are true for all timing measurements. All characteristics are specified at VDDIO = 3.1 - 3.5 V and VSS = 0 V over an operating temperature of -40C to +85C. Pin loadings is 50 pF. The timing values are referenced to 1/2 VDD. DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 15 EP7311 High-Performance, Low-Power System on Chip SDRAM Interface Figure 3 through Figure 6 define the timings associated with all phases of the SDRAM. The following table contains the values for the timings of each of the SDRAM modes. Parameter SDCLK rising edge to SDCS assert delay time SDCLK rising edge to SDCS deassert delay time SDCLK rising edge to SDRAS assert delay time SDCLK rising edge to SDRAS deassert delay time SDCLK rising edge to SDRAS invalid delay time SDCLK rising edge to SDCAS assert delay time SDCLK rising edge to SDCAS deassert delay time SDCLK rising edge to ADDR transition time SDCLK rising edge to ADDR invalid delay time SDCLK rising edge to SDMWE assert delay time SDCLK rising edge to SDMWE deassert delay time DATA transition to SDCLK rising edge time SDCLK rising edge to DATA transition hold time SDCLK rising edge to DATA transition delay time Symbol tCSa tCSd tRAa tRAd tRAnv tCAa tCAd tADv tADx tMWa tMWd tDAs tDAh tDAd Min 0 -3 1 -3 2 -2 -5 -3 -2 -3 -4 2 1 0 Typ 2 2 3 1 4 2 0 1 2 1 0 - Max 4 10 7 10 7 5 3 5 5 5 4 15 Unit ns ns ns ns ns ns ns ns ns ns ns ns ns ns 16 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip SDRAM Load Mode Register Cycle SDCLK tCSa SDCS tRAa SDRAS tRAd tCSd tCAa SDCAS tCAd tADv ADDR tADx DATA SDQM tMWa SDMWE tMWd Figure 3. SDRAM Load Mode Register Cycle Timing Measurement Note: 1. Timings are shown with CAS latency = 2 2. The SDCLK signal may be phase shifted relative to the rest of the SDRAM control and data signals due to uneven loading. Designers should take care to ensure that delays between SDRAM control and data signals are approximately equal DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 17 EP7311 High-Performance, Low-Power System on Chip SDRAM Burst Read Cycle SDCLK tCSa SDCS tCSd tRAa SDRAS tRAd tCSa tCSd tRAnv tCAa SDCAS tADv ADDR tCAd tADv ADRAS ADCAS tDAs tDAs tDAs tDAs DATA D1 tDAh D2 tDAh D3 tDAh D4 tDAh SDQM [0:3] SDMWE Figure 4. SDRAM Burst Read Cycle Timing Measurement Note: 1. Timings are shown with CAS latency = 2 2. The SDCLK signal may be phase shifted relative to the rest of the SDRAM control and data signals due to uneven loading. Designers should take care to ensure that delays between SDRAM control and data signals are approximately equal. 18 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip SDRAM Burst Write Cycle SDCLK tCSa SDCS tRAa SDRAS tRAd tCSd tCSa tCSd tCAa SDCAS tADv ADDR tDAd DATA tADv tCAd ADRAS tDAd tDAd ADCAS tDAd D1 D2 D3 D4 SDQM 0 tMWa tMWd SDMWE Figure 5. SDRAM Burst Write Cycle Timing Measurement Note: 1. Timings are shown with CAS latency = 2 2. The SDCLK signal may be phase shifted relative to the rest of the SDRAM control and data signals due to uneven loading. Designers should take care to ensure that delays between SDRAM control and data signals are approximately equal DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 19 EP7311 High-Performance, Low-Power System on Chip SDRAM Refresh Cycle SDCLK tCSa SDCS tRAa SDRAS tCAd SDCAS tCAa tRAd tCSd SDATA ADDR SDQM [3:0] SDMWE Figure 6. SDRAM Refresh Cycle Timing Measurement Note: 1. Timings are shown with CAS latency = 2 2. The SDCLK signal may be phase shifted relative to the rest of the SDRAM control and data signals due to uneven loading. Designers should take care to ensure that delays between SDRAM control and data signals are approximately equal 20 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Static Memory Figure 7 through Figure 10 define the timings associated with all phases of the Static Memory. The following table contains the values for the timings of each of the Static Memory modes. Parameter EXPCLK rising edge to nCS assert delay time EXPCLK falling edge to nCS deassert hold time EXPCLK rising edge to A assert delay time EXPCLK falling edge to A deassert hold time EXPCLK rising edge to nMWE assert delay time EXPCLK rising edge to nMWE deassert hold time EXPCLK falling edge to nMOE assert delay time EXPCLK falling edge to nMOE deassert hold time EXPCLK falling edge to HALFWORD deassert delay time EXPCLK falling edge to WORD assert delay time EXPCLK rising edge to data valid delay time EXPCLK falling edge to data invalid delay time Data setup to EXPCLK falling edge time EXPCLK falling edge to data hold time EXPCLK rising edge to WRITE assert delay time EXPREADY setup to EXPCLK falling edge time EXPCLK falling edge to EXPREADY hold time Symbol tCSd tCSh tAd tAh tMWd tMWh tMOEd tMOEh tHWd tWDd tDv tDnv tDs tDh tWRd tEXs tEXh Min 2 2 4 3 3 3 3 2 2 2 8 6 5 - Typ 8 7 9 10 6 6 7 7 8 8 13 15 11 - Max 20 20 16 19 10 10 10 10 20 16 21 30 1 3 23 0 0 Unit ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 21 EP7311 High-Performance, Low-Power System on Chip Static Memory Single Read Cycle EXPCLK tCSd nCS tAd A tCSh nMWE tMOEd nMOE tHWd HALFWORD tWDd WORD tDs D tEXs EXPRDY tWRd WRITE tEXh tDh tMOEh Figure 7. Static Memory Single Read Cycle Timing Measurement Note: 1. The cycle time can be extended by integer multiples of the clock period (22 ns at 45 MHz, 27 ns at 36 MHz, 54 ns at 18.432 MHz, and 77 ns at 13 MHz), by either driving EXPRDY low and/or by programming a number of wait states. EXPRDY is sampled on the falling edge of EXPCLK before the data transfer. If low at this point, the transfer is delayed by one clock period where EXPRDY is sampled again. EXPCLK need not be referenced when driving EXPRDY, but is shown for clarity. 2. Address, Halfword, Word, and Write hold state until next cycle. 22 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Static Memory Single Write Cycle EXPCLK tCSd nCS tAd A tMWd nMWE tMWh tCSh nMOE tHWd HALFWORD tWDd WORD tDv D tEXs EXPRDY tEXh WRITE Figure 8. Static Memory Single Write Cycle Timing Measurement Note: 1. The cycle time can be extended by integer multiples of the clock period (22 ns at 45 MHz, 27 ns at 36 MHz, 54 ns at 18.432 MHz, and 77 ns at 13 MHz), by either driving EXPRDY low and/or by programming a number of wait states. EXPRDY is sampled on the falling edge of EXPCLK before the data transfer. If low at this point, the transfer is delayed by one clock period where EXPRDY is sampled again. EXPCLK need not be referenced when driving EXPRDY, but is shown for clarity. 2. Zero wait states for sequential writes is not permitted for memory devices which use nMWE pin, as this cannot be driven with valid timing under zero wait state conditions. 3. Address, Data, Halfword, Word, and Write hold state until next cycle. DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 23 EP7311 High-Performance, Low-Power System on Chip Static Memory Burst Read Cycle EXPCLK tCSd nCS tAd A tAh tAh tAh tCSh nMWE tMOEd nMOE tHWd HALF WORD tMOEh WORD tWDd tDs tDh tDs tDh tDs tDh tDs tDh D tEXs EXPRDY tWRd WRITE tEXh Figure 9. Static Memory Burst Read Cycle Timing Measurement Note: 1. Four cycles are shown in the above diagram (minimum wait states, 1-0-0-0). This is the maximum number of consecutive cycles that can be driven. The number of consecutive cycles can be programmed from 2 to 4, inclusively. 2. The cycle time can be extended by integer multiples of the clock period (22 ns at 45 MHz, 27 ns at 36 MHz, 54 ns at 18.432 MHz, and 77 ns at 13 MHz), by either driving EXPRDY low and/or by programming a number of wait states. EXPRDY is sampled on the falling edge of EXPCLK before the data transfer. If low at this point, the transfer is delayed by one clock period where EXPRDY is sampled again. EXPCLK need not be referenced when driving EXPRDY, but is shown for clarity. 3. Consecutive reads with sequential access enabled are identical except that the sequential access wait state field is used to determine the number of wait states, and no idle cycles are inserted between successive non-sequential ROM/expansion cycles. This improves performance so the SQAEN bit should always be set where possible. 4. Address, Halfword, Word, and Write hold state until next cycle. 24 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Static Memory Burst Write Cycle EXPCLK tCSd nCS tAd A tMWd nMWE tMWh tMWd tMWh tMWd tMWh tMWd tMWh tAh tAh tAh tCSh nMOE tHWd HALF WORD WORD tWDd tDv tDnv tDv tDnv tDv tDnv tDv D tEXs EXPRDY tEXh WRITE Figure 10. Static Memory Burst Write Cycle Timing Measurement Note: 1. Four cycles are shown in the above diagram (minimum wait states, 1-1-1-1). This is the maximum number of consecutive cycles that can be driven. The number of consecutive cycles can be programmed from 2 to 4, inclusively. 2. The cycle time can be extended by integer multiples of the clock period (22 ns at 45 MHz, 27 ns at 36 MHz, 54 ns at 18.432 MHz, and 77 ns at 13 MHz), by either driving EXPRDY low and/or by programming a number of wait states. EXPRDY is sampled on the falling edge of EXPCLK before the data transfer. If low at this point, the transfer is delayed by one clock period where EXPRDY is sampled again. EXPCLK need not be referenced when driving EXPRDY, but is shown for clarity. 3. Zero wait states for sequential writes is not permitted for memory devices which use nMWE pin, as this cannot be driven with valid timing under zero wait state conditions. 4. Address, Data, Halfword, Word, and Write hold state until next cycle. DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 25 EP7311 High-Performance, Low-Power System on Chip SSI1 Interface Parameter ADCCLK falling edge to nADCCSS deassert delay time ADCIN data setup to ADCCLK rising edge time ADCIN data hold from ADCCLK rising edge time ADCCLK falling edge to data valid delay time ADCCLK falling edge to data invalid delay time Symbol tCd tINs tINh tOvd tOd Min 9 -7 -2 Max 10 15 14 13 3 Unit ms ns ns ns ns ADC CLK tCd nADC CSS tINs tINh ADCIN tOvd tOd ADC OUT Figure 11. SSI1 Interface Timing Measurement 26 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip SSI2 Interface Parameter SSICLK period (slave mode) SSICLK high time SSICLK low time SSICLK rise/fall time SSICLK rising edge to RX and/or TX frame sync high time SSICLK rising edge to RX and/or TX frame sync low time SSIRXFR and/or SSITXFR period SSIRXDA setup to SSICLK falling edge time SSIRXDA hold from SSICLK falling edge time SSICLK rising edge to SSITXDA data valid delay time SSITXDA valid time Symbol tclk_per tclk_high tclk_low tclkrf tFRd tFRa tFR_per tRXs tRXh tTXd tTXv Min 185 925 925 3 960 3 3 960 Max 2050 1025 1025 18 3 8 990 7 7 2 990 Unit ns ns ns ns ns ns ns ns ns ns ns tclk_per tclk_high tclk_low SSI CLK tclkrf tFRd tFRa tFR_per SSIRXFR/ SSITXFR tRXh tRXs SSI RXDA tTXd D7 D2 D1 D0 SSI TXDA D7 tTXv D2 D1 D0 Figure 12. SSI2 Interface Timing Measurement DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 27 EP7311 High-Performance, Low-Power System on Chip LCD Interface Parameter CL[2] falling to CL[1] rising delay time CL[1] falling to CL[2] rising delay time CL[1] falling to FRM transition time CL[1] falling to M transition time CL[2] rising to DD (display data) transition time Symbol tCL1d tCL2d tFRMd tMd tDDd Min - 10 Max 25 3,475 10,425 20 20 Unit ns ns ns ns ns 80 300 - 10 - 10 CL[2] tCL1d CL[1] tFRMd FRM tMd M tDDd DD [3:0] tCL2d Figure 13. LCD Controller Timing Measurement 28 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip JTAG Interface Parameter TCK clock period TCK clock high time TCK clock low time JTAG port setup time JTAG port hold time JTAG port clock to output JTAG port high impedance to valid output JTAG port valid output to high impedance Symbol tclk_per tclk_high tclk_low tJPs tJPh tJPco tJPzx tJPxz Min 2 1 1 - Max 0 3 10 12 19 Units ns ns ns ns ns ns ns ns tclk_per tclk_high TCK tJPs TMS tJPh tclk_low TDI tJPzx TDO tJPco tJPxz Figure 14. JTAG Timing Measurement DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 29 EP7311 High-Performance, Low-Power System on Chip Packages 208-Pin LQFP Package Characteristics 208-Pin LQFP Package Specifications 29.60 (1.165) 30.40 (1.197) 27.80 (1.094) 28.20 (1.110) 0.17 (0.007) 0.27 (0.011) 27.80 (1.094) 28.20 (1.110) 29.60 (1.165) 30.40 (1.197) EP7311 208-Pin LQFP 0.50 (0.0197) BSC Pin 1 Indicator Pin 208 Pin 1 0.45 (0.018) 0.75 (0.030) 1.35 (0.053) 1.45 (0.057) 1.00 (0.039) BSC 0.09 (0.004) 0.20 (0.008) 1.40 (0.055) 1.60 (0.063) 0.05 (0.002) 0.15 (0.006) 0 MIN 7 MAX Figure 15. 208-Pin LQFP Package Outline Drawing Note: 1) Dimensions are in millimeters (inches), and controlling dimension is millimeter. 2) Drawing above does not reflect exact package pin count. 3) Before beginning any new design with this device, please contact Cirrus Logic for the latest package information. 4) For pin locations, please see Figure 16. For pin descriptions see the EP7311 User's Manual. 30 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip 208-Pin LQFP Pin Diagram nURESET nMEDCHG/nBROM nPOR BATOK nEXTPWR nBATCHG D[7] VSSIO A[7] D[8] A[8] D[9] A[9] D[10] A[10] D[11] VSSIO VDDIO A[11] D[12] A[12] D[13] A[13]\DRA[14] D[14] A[14]/DRA[13] D[15] A[15]/DRA[12] D[16] A[16]/DRA[11] D[17] A[17]/DRA[10] nTRST VSSIO VDDIO D[18] A[18/DRA[9] D[19] A[19]/DRA[8] D[20] A[20]/DRA[7] VSSIO D[21] A[21]/DRA[6] D[22] A[22]/DRA[5] D[23] A[23]/DRA[4] D[24] VSSIO VDDIO A[24]/DRA[3] HALFWORD 156 155 154 153 152 151 150 149 148 147 146 145 144 143 142 141 140 139 138 137 136 135 134 133 132 131 130 129 128 127 126 125 124 123 122 121 120 119 118 117 116 115 114 113 112 111 110 109 108 107 106 105 Note: 1. N/C should not be grounded but left as no connects. 2. Pin differences between the EP7211 and the EP7311 are bolded. DS506F1 nCS[5] VDDIO VSSIO EXPCLK WORD WRITE/nSDRAS RUN/CLKEN EXPRDY TXD[2] RXD[2] TDI VSSIO PB[7] PB[6] PB[5] PB[4] PB[3] PB[2] PB[1] PB[0] VDDIO TDO PA[7] PA[6] PA[5] PA[4] PA[3] PA[2] PA[1] PA[0] LEDDRV TXD[1] VSSIO PHDIN CTS RXD[1] DCD DSR nTEST[1] nTEST[0] EINT[3] nEINT[2] nEINT[1] nEXTFIQ PE[2]/CLKSEL PE[1]BOOTSEL[1] PE[0]BOOTSEL[0] VSSRTC RTCOUT RTCIN VDDRTC N/C 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 VDDOSC MOSCIN MOSCOUT VSSOSC WAKEUP nPWRFL A[6] D[6] A[5] D[5] VDDIO VSSIO A[4] D[4] A[3] D[3] A[2] VSSIO D[2] A[1] D[1] A[0] D[0] VSSCORE VDDCORE VSSIO VDDIO CL[2] CL[1] FRM M DD[3] DD[2] VSSIO DD[1] DD[0] nSDCS[1] nSDCS[0] SDQM[3] SDQM[2] VDDIO VSSIO SDCKE SDCLK nMWE/nSDWE nMOE/nSDCAS VSSIO nCS[0] nCS[1] nCS[2] nCS[3] nCS[4] 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 EP7311 208-Pin LQFP (Top View) 104 103 102 101 100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 D[25] A[25]/DRA[2] D[26] A[26]/DRA[1] D[27] A[27]/DRA[0] VSSIO D[28] D[29] D[30] D[31] BUZ COL[0] COL[1] TCLK VDDIO COL[2] COL[3] COL[4] COL[5] COL[6] COL[7] FB[0] VSSIO FB[1] SMPCLK ADCOUT ADCCLK DRIVE[0] DRIVE[1] VDDIO VSSIO VDDCORE VSSCORE nADCCS ADCIN SSIRXFR SSIRXDA SSITXDA SSITXFR VSSIO SSICLK PD[0]/LEDFLSH PD[1] PD[2] PD[3] TMS VDDIO PD[4] PD[5] PD[6]/SDQM[0] PD[7]/SDQM[1] Figure 16. 208-Pin LQFP (Low Profile Quad Flat Pack) Pin Diagram (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 31 EP7311 High-Performance, Low-Power System on Chip 208-Pin LQFP Numeric Pin Listing Table T. 208-Pin LQFP Numeric Pin Listing Table T. 208-Pin LQFP Numeric Pin Listing (Continued) Pin No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 Signal nCS[5] VDDIO VSSIO EXPCLK WORD WRITE/nSDRAS RUN/CLKEN EXPRDY TXD[2] RXD[2] TDI VSSIO PB[7] PB[6] PB[5] PB[4] PB[3] PB[2] PB[1]/PRDY2 PB[0]/PRDY1 VDDIO TDO PA[7] PA[6] PA[5] PA[4] PA[3] PA[2] PA[1] PA[0] LEDDRV TXD[1] VSSIO PHDIN CTS RXD[1] Type O Pad Pwr Pad Gnd I/O Out Out O I O I I Pad Gnd I/O I/O I/O I/O I/O I/O I/O I/O Pad Pwr O I/O I/O I/O I/O I/O I/O I/O I/O O O Pad Gnd I I I Strength 1 Reset State Low Pin No. 37 38 39 Signal DCD DSR nTEST[1] nTEST[0] EINT[3] nEINT[2] nEINT[1] nEXTFIQ PE[2]/CLKSEL PE[1]/ BOOTSEL[1] PE[0]/ BOOTSEL[0] VSSRTC RTCOUT RTCIN VDDRTC N/C PD[7]/SDQM[1] PD[6]/SDQM[0] PD[5] PD[4] VDDIO TMS PD[3] PD[2] PD[1] PD[0]/LEDFLSH SSICLK VSSIO SSITXFR SSITXDA SSIRXDA SSIRXFR ADCIN nADCCS VSSCORE VDDCORE Type I I I I I I I I I/O I/O I/O RTC Gnd O I RTC power Strength Reset State With p/u* With p/u* 1 1 1 1 1 1 High Low Low Low 40 41 42 43 44 45 46 1 1 1 Input Input Input with p/u* 47 1 1 1 1 1 1 1 1 Input Input Input Input Input Input Input Input 48 49 50 51 52 53 54 55 56 1 1 1 1 1 1 1 1 1 1 1 1 Three state Input Input Input Input Input Input Input Input Low High High 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 I/O I/O I/O I/O Pad Pwr I I/O I/O I/O I/O I/O Pad Gnd I/O O I I/O I O Core Gnd Core Pwr 1 1 1 1 Low Low Low Low with p/u* 1 1 1 1 1 Low Low Low Low Input 1 1 Low Low Input 1 High 32 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Table T. 208-Pin LQFP Numeric Pin Listing (Continued) Table T. 208-Pin LQFP Numeric Pin Listing (Continued) Pin No. 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 Signal VSSIO VDDIO DRIVE[1] DRIVE[0] ADCCLK ADCOUT SMPCLK FB[1] VSSIO FB[0] COL[7] COL[6] COL[5] COL[4] COL[3] COL[2] VDDIO TCLK COL[1] COL[0] BUZ D[31] D[30] D[29] D[28] VSSIO A[27]/DRA[0] D[27] A[26]/DRA[1] D[26] A[25]/DRA[2] D[25] HALFWORD A[24]/DRA[3] VDDIO VSSIO D[24] Type Pad Gnd Pad Pwr I/O I/O O O O I Pad Gnd I O O O O O O Pad Pwr I O O O I/O I/O I/O I/O Pad Gnd O I/O O I/O O I/O O O Pad Pwr Pad Gnd I/O Strength Reset State Pin No. 110 111 Signal A[23]/DRA[4] D[23] A[22]/DRA[5] D[22] A[21]/DRA[6] D[21] VSSIO A[20]/DRA[7] D[20] A[19]/DRA[8] D[19] A[18]/DRA[9] D[18] VDDIO VSSIO nTRST A[17]/DRA[10] D[17] A[16]/DRA[11] D[16] A[15]/DRA[12] D[15] A[14]/DRA[13] D[14] A[13]/DRA[14] D[13] A[12] D[12] A[11] VDDIO VSSIO D[11] A[10] D[10] A[9] D[9] A[8] D[8] Type O I/O O I/O O I/O Pad Gnd O I/O O I/O O I/O Pad Pwr Pad Gnd I O I/O O I/O O I/O O I/O O I/O O I/O O Pad Pwr Pad Gnd I/O O I/O O I/O O I/O Strength 1 1 1 1 1 1 Reset State Low Low Low Low Low Low 2 2 1 1 1 High / Low High / Low Low Low Low 112 113 114 115 116 117 118 119 120 1 1 1 1 1 1 Low Low Low Low Low Low 1 1 1 1 1 1 High High High High High High 121 122 123 124 125 126 127 128 1 1 1 1 1 1 1 1 1 1 1 1 1 Low Low Low Low Low Low Low Low Low Low Low Low Low 1 1 1 1 1 1 1 High High Low Low Low Low Low 129 130 131 132 133 134 135 136 2 1 2 1 2 1 1 1 Low Low Low Low Low Low Low Low -- -- 137 138 139 140 141 142 143 144 145 146 147 1 1 1 1 1 1 1 Low Low Low Low Low Low Low 1 Low DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 33 EP7311 High-Performance, Low-Power System on Chip Table T. 208-Pin LQFP Numeric Pin Listing (Continued) Table T. 208-Pin LQFP Numeric Pin Listing (Continued) Pin No. 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 Signal A[7] VSSIO D[7] nBATCHG nEXTPWR BATOK nPOR nMEDCHG/ nBROM nURESET VDDOSC MOSCIN MOSCOUT VSSOSC WAKEUP nPWRFL A[6] D[6] A[5] D[5] VDDIO VSSIO A[4] D[4] A[3] D[3] A[2] VSSIO D[2] A[1] D[1] A[0] D[0] VSS CORE VDD CORE VSSIO VDDIO CL[2] CL[1] Type O Pad Gnd I/O I I I I I I Osc Pwr Osc Osc Osc Gnd I I O I/O Out I/O Pad Pwr Pad Gnd O I/O O I/O O Pad Gnd I/O O I/O O I/O Core Gnd Core Pwr Pad Gnd Pad Pwr O O Strength 1 Reset State Low Pin No. 186 187 Signal FRM M DD[3] DD[2] VSSIO DD[1] DD[0] nSDCS[1] nSDCS[0] SDQM[3] SDQM[2] VDDIO VSSIO SDCKE SDCLK nMWE/nSDWE nMOE/nSDCAS VSSIO nCS[0] nCS[1] nCS[2] nCS[3] nCS[4] Type O O I/O I/O Pad Gnd I/O I/O O O I/O I/O Pad Pwr Pad Gnd I/O I/O O O Pad Gnd O O O O O Strength 1 1 1 1 Reset State Low Low Low Low 1 Low 188 189 190 191 1 1 1 1 2 2 Low Low High High Low Low Schmitt 192 193 194 Schmitt 195 196 197 198 199 2 2 1 1 Low Low High High Schmitt 200 201 Low Low Low Low 1 1 1 1 202 203 204 205 206 207 1 1 1 1 1 High High High High High 1 1 2 1 2 Low Low Low Low Low 208 *With p/u' means with internal pull-up on the pin. 1 2 1 2 1 Low Low Low Low Low 1 1 Low Low 34 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip 204-Ball TFBGA Package Characteristics 204-Ball TFBGA Package Specifications TOP VIEW A1 CORNER 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 A B C D E F G H J K L M N P R T U V W Y O0.08 M C BOTTOM VIEW A1 CORNER A B C D E F G H J K L M N P R T U V W Y 0.65 12.35 O0.15 M C A B O0.25~0.35(204X) 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 130.05 A 12.35 0.65 B 0.530.05 0.20 C 0.15(4X) C 130.05 0.10 C Ball Pitch : 0.65 0.36 1.20 MAX. 0.20~0.30 C Substrate Thickness : 0.36 Mold Thickness : 0.53 SEATING PLANE Ball Diameter : 0.3 Figure 17. 204-Ball TFBGA Package DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 35 EP7311 High-Performance, Low-Power System on Chip 204-Ball TFBGA Pinout (Top View) 1 2 3 4 nCS1 5 6 7 8 DD2 9 FRM 10 CL1 11 GNDCOR E D0 12 D1 13 A2 14 D4 15 A5 16 17 18 19 GNDIO 20 GNDIO A A VDDIO EXPCLK nCS3 nMWE/ SDQM2 nSDCS1 nSDWE nMOE/ SDCKE nSDCS0 nSDCAS nCS0 SDCLK SDQM3 nPWRFL MOSCOUT GNDIO B WORD VDDIO nCS5 nCS2 DD1 M CL2 VDDCO RE A1 D3 A4 D6 WAKEUP MOSCIN GNDOS VDDOSC C GNDIO GNDIO nURESET B C RUN/ EXPRDY VDDIO CLKEN PB7 RXD2 VDDIO WRITE/ nSDRAS TDI nCS4 DD0 DD3 A0 D2 A3 D5 A6 GNDIO BATOK nPOR C D GNDIO nBATCHG nMEDCHG nEXTPWR /nBROM D7 A8 A7 D E PB4 TXD2 D9 E F PB3 PB1/ PRDY2 PA7 PB6 D10 F G PB2 PB5 PB0/ PRDY1 PA6 D8 A9 D11 G H TDO A10 D12 A12 A13/ DRA14 D15 A16/ DRA11 H J PA4 PA5 A11 D13 A14/ DRA13 D16 A17/ DRA10 D19 A20/ DRA7 D22 J K PA1 PA2 VDDIO D14 K L TXD1 LEDDRV PA3 VDDIO A15/ DRA12 D17 L M RXD1 CTS PA0 nTRST M A18/ DRA9 D20 A21/ DRA6 A22/ DRA5 A23/ DRA4 A24/ DRA3 D25 N DSR nTEST1 PHDIN N P EINT3 nEINT2 DCD D18 A19/ DRA8 P R nEXTFIQ PE1/ BOOT SEL1 PE2/ nTEST0 CLKSEL PE0/ BOOT SEL0 R T nEINT1 D21 D23 T U GNDRTCRTCOUT RTCIN PD7/ SDQM1 A26/ DRA1 A27/ DRA0 HALF WORD PD4 PD2 SSICLK SSIRXDA nADCCS VDDIO ADCCLK COL7 GNDCO DRIVE1 ADCOUT RE COL4 TCLK BUZ D29 VDDIO D24 U V VDDRTC GNDIO GNDIO VDDIO V W GNDIO GNDIO GNDIO PD6/SD TMS QM0 PD1 SSITXFR SSIRXFR FB0 COL5 COL2 COL0 D30 D26 VDDIO W Y GNDIO GNDIO GNDIO PD5 PD3 PD0/ VDDCO LED SSITXDA ADCIN DRIVE0 SMPLCK RE FLSH FB1 COL6 COL3 COL1 D31 D28 D27 A25/ DRA2 VDDIO Y 36 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip 204-Ball TFBGA Ball Listing The list is ordered by ball location. Table 21. 204-Ball TFBGA Ball Listing Ball Location Name Strength Reset State Type Description A1 VDDIO Pad power Digital I/O power, 3.3 V Expansion clock input Chip select 3 Chip select 1 ROM, expansion write enable/ SDRAM write enable control signal SDRAM byte lane mask SDRAM chip select 2 LCD serial display data LCD frame synchronization pulse LCD line clock Core ground Data I/O System byte address Data I/O System byte address Power fail sense input Main oscillator out I/O ground I/O ground I/O ground Word access select output Digital I/O power, 3.3 V Chip select 5 Chip select 2 ROM, expansion OP enable/SDRAM CAS control signal SDRAM clock enable output SDRAM chip select 0 A2 A3 A4 EXPCLK nCS[3] nCS[1] 1 1 1 High High I O O A5 nMWE/nSDWE 1 High O A6 SDQM[2] 2 Low O A7 nSDCS[1] 1 High O A8 DD[2] 1 Low O A9 FRM 1 Low O A10 A11 A12 A13 A14 A15 A16 A17 A18 A19 A20 B1 CL[1] VSSCORE D[1] A[2] D[4] A[5] nPWRFL MOSCOUT VSSIO VSSIO VSSIO WORD 1 Low O Core ground 1 2 1 1 Low Low Low Low I/O O I/O O I O Pad ground Pad ground Pad ground 1 Low O B2 B3 B4 VDDIO nCS[5] nCS[2] 1 1 Low High Pad power O O B5 nMOE/nSDCAS 1 High O B6 SDCKE 2 Low O B7 nSDCS[0] 1 High O DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 37 EP7311 High-Performance, Low-Power System on Chip Table 21. 204-Ball TFBGA Ball Listing (Continued) Ball Location Name Strength Reset State Type Description B8 B9 B10 B11 B12 B13 B14 B15 B16 B17 B18 B19 B20 C1 DD[1] M CL[2] D[0] A[1] D[3] A[4] D[6] WAKEUP MOSCIN VSSIO VSSIO nURESET RUN/CLKEN 1 1 1 1 2 2 1 1 Schmitt Low Low Low Low Low Low Low Low O O 0 I/O O I/O O I/O I I Pad ground Pad ground LCD serial display data LCD AC bias drive LCD pixel clock out Data I/O System byte address Data I/O System byte address Data I/O System wake up input Main oscillator input I/O ground I/O ground User reset input Run output / clock enable output Expansion port ready input Digital I/O power, 3.3 V Chip select 4 Chip select 0 SDRAM clock out SDRAM byte lane mask LCD serial display data LCD serial display data Digital core power, 2.5 V System byte address Data I/O System byte address Data I/O System byte address PLL ground Oscillator power in, 2.5V I/O ground Battery ok input Schmitt 1 Low I 0 C2 EXPRDY 1 I C3 C4 C5 C6 C7 VDDIO nCS[4] nCS[0] SDCLK SDQM[3] 1 1 2 2 High High Low Low Pad power O O O O C8 DD[0] 1 Low O C9 DD[3] 1 Low O C10 C11 C12 C13 C14 C15 C16 C17 C18 C19 VDDCORE A[0] D[2] A[3] D[5] A[6] VSSOSC VDDOSC VSSIO BATOK 2 1 2 1 1 Low Low Low Low Low Core power O I/O O I/O O Oscillator ground Oscillator power Pad ground I 38 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Table 21. 204-Ball TFBGA Ball Listing (Continued) Ball Location Name Strength Schmitt 1 Reset State Type Description C20 D1 nPOR PB[7] I Power-on reset input GPIO port B UART 2 receive data input Digital I/O power, 3.3V I/O ground Battery changed sense input System byte address GPIO port B UART 2 transmit data output Transfer direction / SDRAM RAS signal output Media change interrupt input / internal ROM boot enable External power supply sense input Data I/O GPIO port B GPIO port B Input I D2 RXD[2] I D3 D18 D19 D20 E1 VDDIO VSSIO nBATCHG A[7] PB[4] 1 1 Low Pad power Pad ground I O I Input E2 TXD[2] 1 High O E3 WRITE/nSDRAS 1 Low O E18 nMEDCHG/nBROM I E19 E20 F1 nEXTPWR D[9] PB[3] 1 1 Low I I/O I/O Input F2 F3 F18 F19 F20 G1 PB[6] TDI D[7] A[8] D[10] PB[1] 1 with p/u* 1 1 1 1 Input I/O I JTAG data input Data I/O System byte address Data I/O Low Low Low I/O O I/O I/O Input G2 PB[2] 1 Input I/O GPIO port B G3 PB[5] 1 Input I/O GPIO port B G18 G19 G20 H1 D[8] A[9] D[11] PA[7] 1 1 1 1 Input I/O O I/O I/O Data I/O System byte address Data I/O GPIO port A Low Low Input H[2] TDO 1 Input O JTAG data out H[3] H[18] PB[0] A[10] 1 1 Input I/O O GPIO port B System byte address Low DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 39 EP7311 High-Performance, Low-Power System on Chip Table 21. 204-Ball TFBGA Ball Listing (Continued) Ball Location Name Strength 1 1 1 Reset State Low Low Type Description H19 H20 J1 D[12] A[12] PA[4] I/O O I/O Data I/O System byte address GPIO port A Input J2 PA[5] 1 Input I/O GPIO port A J3 J18 J19 J20 PA[6] A[11] D[13] A[13]/DRA[14] 1 1 1 1 Input I/O O I/O O GPIO port A System byte address Data I/O System byte address / SDRAM address GPIO port A Low Low Low K1 PA[1] 1 Input I/O K2 PA[2] 1 Input I/O GPIO port A Digital I/O power, 3.3V Data I/O System byte address / SDRAM address Data I/O UART 1 transmit data out IR LED drive GPIO port A Digital I/O power, 3.3V Data I/O System byte address / SDRAM address UART 1 receive data input UART 1 clear to send input GPIO port A System byte address / SDRAM address System byte address / SDRAM address JTAG async reset input UART 1 data set ready input Test mode select input Photodiode input K3 K18 K19 K20 L1 L2 L3 VDDIO D[14] A[14]/DRA[13] D[15] TXD[1] LEDDRV PA[3] 1 1 1 1 1 1 Low Low Low High Low Pad power I/O O I/O O O I/O Input L18 L19 L20 VDDIO D[16] A[16]/DRA[11] 1 1 Low Low Pad power I/O O M1 RXD[1] I M2 CTS I M3 PA[0] 1 Input I/O M18 A[15]/DRA[12] 1 Low O M19 A[17]/DRA[10] 1 Low O M20 nTRST I N1 DSR I N2 N3 nTEST[1] PHDIN With p/u* I I 40 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Table 21. 204-Ball TFBGA Ball Listing (Continued) Ball Location Name Strength 1 1 1 Reset State Low Low Low Type Description N18 N19 N20 P1 P2 D[17] D[19] A[18]/DRA[9] EINT[3] nEINT[2] I/O I/O O I I Data I/O Data I/O System byte address / SDRAM address External interrupt External interrupt input UART 1 data carrier detect Data I/O System byte address / SDRAM address Data I/O External fast interrupt input GPIO port E / clock input mode select Test mode select input System byte address / SDRAM address Data I/O System byte address / SDRAM address GPIO port E / boot mode select GPIO port E / boot mode select External interrupt input Data I/O Data I/O System byte address / SDRAM address Real time clock ground Real time clock oscillator output Real time clock oscillator input Halfword access select output Data I/O System byte address / SDRAM address Real time clock power, 2.5V P3 P18 P19 P20 R1 DCD D[18] A[20]/DRA[7] D[20] nEXTFIQ 1 1 1 Low Low Low I I/O O I/O I R2 PE[2]/CLKSEL 1 Input I/O R3 nTEST[0] With p/u* I R18 R19 R20 A[19]/DRA[8] D[22] A[21]/DRA[6] 1 1 1 Low Low Low O I/O O T1 PE[1]/BOOTSEL[1] 1 Input I/O T2 PE[0]/BOOTSEL[0] 1 Input I/O T3 T18 T19 T20 nEINT[1] D[21] D[23] A[22]/DRA[5] 1 1 1 Low Low Low I I/O I/O O U1 VSSRTC RTC ground U2 RTCOUT O U3 RTCIN I/O U18 U19 U20 HALFWORD D[24] A[23]/DRA[4] 1 1 1 Low Low Low O I/O O V1 VDDRTC RTC power DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 41 EP7311 High-Performance, Low-Power System on Chip Table 21. 204-Ball TFBGA Ball Listing (Continued) Ball Location Name Strength Reset State Type Description V2 V3 VSSIO VSSIO Pad ground Pad ground I/O ground I/O ground GPIO port D / SDRAM byte lane mask GPIO port D GPIO port D DAI/CODEC/SSI2 serial clock DAI/CODEC/SSI2 serial data input SSI1 ADC chip select Digital I/O power, 3.3V SSI1 ADC serial clock Keyboard scanner column drive Keyboard scanner column drive JTAG clock Buzzer drive output Data I/O System byte address / SDRAM address Digital I/O power, 3.3 V Digital I/O power, 3.3 V System byte address / SDRAM address I/O ground I/O ground I/O ground GPIO port D / SDRAM byte lane mask JTAG mode select GPIO port D DAI/CODEC/SSI2 frame sync DAI/CODEC/SSI2 frame sync Core Ground PWM drive output V4 PD[7]/SDQM[1] 1 Low I/O V5 V6 V7 PD[4] PD[2] SSICLK 1 1 1 Low Low I/O I/O I/O Input V8 SSIRXDA I/O V9 nADCCS 1 High O V10 VDDIO Pad power V11 ADCCLK 1 Low O V12 COL[7] 1 High O V13 V14 V15 V16 V17 COL[4] TCLK BUZ D[29] A[26]/DRA[1] 1 High O I 1 1 2 Low Low Low O I/O O V18 VDDIO Pad power V19 VDDIO Pad power V20 W1 W2 W3 A[24]/DRA[3] VSSIO VSSIO VSSIO ` Low O Pad ground Pad ground Pad ground W4 PD[6]/SDQM[0] 1 Low I/O W5 W6 W7 TMS PD[1] SSITXFR with p/u* 1 1 Low Low I I/O I/O W8 W9 W10 SSIRXFR VSSCORE DRIVE[1] 1 Input I/O Core Ground 2 High / Low I/O 42 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Table 21. 204-Ball TFBGA Ball Listing (Continued) Ball Location Name Strength Reset State Type Description W11 W12 W13 ADCOUT FB[0] COL[5] 1 Low O I SSI1 ADC serial data output PWM feedback input Keyboard scanner column drive Keyboard scanner column drive Keyboard scanner column drive Data I/O System byte address / SDRAM address Data I/O Digital I/O power, 3.3V Data I/O I/O ground I/O ground I/O ground GPIO port D GPIO port D GPIO port D / LED blinker output DAI/CODEC/SSI2 serial data output SSI1 ADC serial input Digital core power, 2.5V PWM drive output SSI1 ADC sample clock PWM feedback input Keyboard scanner column drive Keyboard scanner column drive Keyboard scanner column drive Data I/O Data I/O Data I/O System byte address / SDRAM address 1 High O W14 COL[2] 1 High O W15 W16 W17 W18 W19 W20 Y1 Y2 Y3 Y4 Y5 Y6 COL[0] D[30] A[27]/DRA[0] D[26] VDDIO D[25] VSSIO VSSIO VSSIO PD[5] PD[3] PD[0]/LEDFLSH 1 1 2 1 High Low Low Low O I/O O I/O Pad power 1 Low I/O Pad ground Pad ground Pad ground 1 1 1 Low Low Low I/O I/O I/O Y7 SSITXDA 1 Low O Y8 ADCIN I Y9 VDDCORE Core power Y10 DRIVE[0] 2 Input I/O Y11 Y12 Y13 SMPCLK FB[1] COL[6] 1 Low O I 1 High O Y14 COL[3] 1 High O Y15 Y16 Y17 Y18 Y19 COL[1] D[31] D[28] D[27] A[25]/DRA[2] 1 1 1 1 2 High Low Low Low Low O I/O I/O I/O O DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 43 EP7311 High-Performance, Low-Power System on Chip Table 21. 204-Ball TFBGA Ball Listing (Continued) Ball Location Name Strength Reset State Type Description Y20 VDDIO Pad power Digital I/O power, 3.3V * "With p/u" means with internal pull-up of 100 KOhms on the pin. Strength 1 = 4 ma Strength 2 = 12 ma Input. Port A,B,D,E GPIOs default to input at nPOR and URESET conditions. 256-Ball PBGA Package Characteristics 256-Ball PBGA Package Specifications Figure 18. 256-Ball PBGA Package Note: 1) For pin locations see Table V. 2) Dimensions are in millimeters (inches), and controlling dimension is millimeter 3) Before beginning any new EP7311 design, contact Cirrus Logic for the latest package information. 256-Ball PBGA Pinout (Top View) 1 A VDDIO 2 nCS[4] 3 nCS[1] 4 SDCLK nMOE/ nSDCAS VDDIO 5 SDQM[3] 6 DD[1] 7 M 8 VDDIO 9 D[0] 10 D[2] 11 A[3] 12 VDDIO 13 A[6] 14 15 16 VSSIO A MOSCOUT VDDOSC B nCS[5] VDDIO nCS[3] VDDIO nSDCS[1] DD[2] CL[1] VDDCORE D[1] A[2] A[4] A[5] WAKEUP VDDIO nURESET B C VDDIO WRITE/ nSDRAS RXD[2] EXPCLK VSSIO VSSIO VSSIO nMWE/ nSDWE nCS[0] VSSIO VDDIO VSSIO VSSIO VSSIO VDDIO VSSIO VSSIO nPOR nEXTPWR C D EXPRDY VSSIO VDDIO nCS[2] nSDCS[0] CL[2] VSSRTC D[4] nPWRFL MOSCIN VDDIO nMEDCHG/ nBROM nBATCHG VSSIO D[7] D[8] D E PB[7] TDI WORD VSSIO RUN/ CLKEN PB[6] SDQM[2] FRM A[0] D[5] VSSOSC VSSIO VDDIO D[9] D[10] E F PB[5] PB[3] VSSIO TXD[2] VSSIO SDCKE DD[3] A[1] D[6] VSSRTC BATOK VSSIO D[11] VDDIO F G PB[1] VDDIO TDO PB[4] VSSRTC VSSRTC DD[0] D[3] VSSRTC A[7] A[8] A[9] A[13]/ DRA[14] A[14]/ DRA[13] D[18] A[21]/ DRA[6] A[23]/ DRA[4] HALFWORD VSSIO D[12] D[13] G H PA[7] PA[5] VSSIO PA[4] PA[6] PB[0] PB[2] VSSRTC VSSRTC A[10] A[17]/ DRA[10] TCLK A[11] A[16]/ DRA[11] D[20] A[12] A[15]/ DRA[12] D[19] A[22]/ DRA[5] VSSIO VSSIO D[14] D[15] H J PA[3] PA[1] VSSIO PA[2] PA[0] TXD[1] CTS VSSRTC VSSRTC nTRST D[16] D[17] J K LEDDRV PHDIN VSSIO DCD nTEST[1] PE[2]/ CLKSEL TMS EINT[3] VSSRTC ADCIN COL[4] VSSIO VDDIO A[18]/ DRA[9] A[20]/ DRA[7] D[22] VDDIO A[19]/ DRA[8] D[21] K L RXD[1] DSR VDDIO nEINT[1] PE[0]/ BOOTSEL[0] VDDIO VSSRTC PD[0]/ VSSRTC LEDFLSH SSITXFR DRIVE[1] COL[6] D[31] VSSRTC VSSIO L M nTEST[0] nEINT[2] VDDIO VDDIO FB[0] COL[0] D[27] VDDIO M N nEXTFIQ PE[1]/ VSSIO BOOTSEL[1] RTCOUT VSSIO PD[5] PD[2] SSIRXDA ADCCLK SMPCLK COL[2] D[29] D[26] VSSIO D[23] N P VSSRTC VSSIO VDDIO VSSIO VSSIO VDDIO VSSIO VDDIO VSSIO VSSIO VDDIO A[27]/ DRA[0] D[28] VSSIO A[25]/ DRA[2] A[26]/ DRA[1] D[24] VDDIO A[24]\ DRA[3] VSSIO P R RTCIN VDDIO PD[7]/ SDQM[1] PD[4] PD[6]/ SDQM[0] PD[1] SSITXDA nADCCS VDDIO ADCOUT COL[7] COL[3] COL[1] D[30] VDDIO R T VDDRTC PD[3] SSICLK SSIRXFR VDDCORE DRIVE[0] FB[1] COL[5] VDDIO BUZ D[25] T 44 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip 0.85 (0.034) 0.05 (.002) 17.00 (0.669) 0.20 (.008) Pin 1 Corner 15.00 (0.590) 0.20 (.008) 30 TYP 0.40 (0.016) 0.05 (.002) D1 17.00 (0.669) 0.20 (.008) Pin 1 Indicator E1 15.00 (0.590) 0.20 (.008) 2 Layer 0.36 (0.014) 0.09 (0.004) TOP VIEW SIDE VIEW D 17.00 (0.669) 1.00 (0.040) REF 1.00 (0.040) Pin 1 Corner E 16 15 14 13 12 11 10 9 8 7 65 432 1 1.00 (0.040) REF 1.00 (0.040) A B C D E F G H J K L M N P R T BOTTOM VIEW 17.00 (0.669) 0.50 R 3 Places JEDEC #: MO-151 Ball Diameter: 0.50 mm 0.10 mm 17 17 1.61 mm body DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 45 EP7311 High-Performance, Low-Power System on Chip 256-Ball PBGA Ball Listing The list is ordered by ball location. Table V. 256-Ball PBGA Ball Listing Ball Location A1 A2 A3 A4 A5 A6 A7 A8 A9 A10 A11 A12 A13 A14 A15 A16 B1 B2 B3 B4 B5 B6 B7 B8 B9 B10 B11 B12 B13 B14 B15 B16 C1 C2 C3 C4 C5 C6 C7 C8 C9 C10 C11 Name VDDIO nCS[4] nCS[1] SDCLK SDQM[3] DD[1] M VDDIO D[0] D[2] A[3] VDDIO A[6] MOSCOUT VDDOSC VSSIO nCS[5] VDDIO nCS[3] nMOE/nSDCAS VDDIO nSDCS[1] DD[2] CL[1] VDDCORE D[1] A[2] A[4] A[5] WAKEUP VDDIO nURESET VDDIO EXPCLK VSSIO VDDIO VSSIO VSSIO VSSIO VDDIO VSSIO VSSIO VSSIO Type Pad power O O O O O O Pad power I/O I/O O Pad power O O Oscillator power Description C12 Digital I/O power, 3.3V C13 Chip select out C14 Chip select out C15 SDRAM clock out C16 SDRAM byte lane mask LCD serial display data LCD AC bias drive Digital I/O power, 3.3V Data I/O Data I/O System byte address Digital I/O power, 3.3V D7 System byte address D8 Main oscillator out D9 Oscillator power in, 2.5V D10 D11 D12 D13 D14 D15 D16 Pad power O O O Digital I/O power, 3.3V E1 SDRAM chip select out E2 LCD serial display data E3 LCD line clock E4 Core power Digital core power, 2.5V E5 I/O O O O I Pad power I Pad power I Data I/O E6 System byte address E7 System byte address E8 System byte address E9 System wake up input E10 Digital I/O power, 3.3V User reset input Digital I/O power, 3.3V Expansion clock input E11 E12 E13 E14 Pad power Digital I/O power, 3.3V E15 Pad ground I/O ground E16 Pad ground I/O ground F1 Pad ground I/O ground F2 Pad power Digital I/O power, 3.3V F3 Pad ground I/O ground F4 Pad ground I/O ground F5 Pad ground I/O ground F6 VSSIO Pad ground I/O ground RUN/CLKEN O Run output / clock enable output TXD[2] O UART 2 transmit data output VSSIO Pad ground I/O ground PB[3] I GPIO port B PB[5] I GPIO port B D[10] I/O Data I/O D[9] I/O Data I/O VSSOSC VSSIO nMEDCHG/nBROM VDDIO Oscillator ground PLL ground D[5] I/O Data I/O A[0] O System byte address FRM O LCD frame synchronization pulse SDQM[2] O SDRAM byte lane mask nCS[0] O Chip select out VSSIO Pad ground I/O ground WORD O Word access select output TDI I JTAG data input PB[7] I GPIO port B RXD[2] I UART 2 receive data input VSSRTC D[4] nPWRFL MOSCIN VDDIO VSSIO D[7] D[8] Core ground Real time clock ground I/O I I Pad power Data I/O Power fail sense input Main oscillator input Digital I/O power, 3.3V CL[2] O LCD pixel clock out nSDCS[0] O SDRAM chip select out D1 D2 D3 D4 D5 D6 WRITE/nSDRAS EXPRDY VSSIO VDDIO nCS[2] nMWE/nSDWE O I Transfer direction / SDRAM RAS signal output Expansion port ready input nEXTPWR I External power supply sense input nPOR I Power-on reset input VSSIO Pad ground I/O ground VSSIO Pad ground I/O ground VDDIO Pad power Digital I/O power, 3.3V Table V. 256-Ball PBGA Ball Listing (Continued) Ball Location Name Type Description Pad ground I/O ground Pad power O O Digital I/O power, 3.3V Chip select out ROM, expansion write enable/ SDRAM write enable control signal Pad ground I/O ground O Pad power O O Chip select out I/O ground Chip select out ROM, expansion OP enable/SDRAM CAS control signal Pad ground I/O ground I/O I/O Data I/O Data I/O Pad ground I/O ground I Pad power Media change interrupt input / internal ROM boot enable Digital I/O power, 3.3V Pad ground I/O ground 46 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Table V. 256-Ball PBGA Ball Listing (Continued) Ball Location F7 F8 F9 F10 F11 F12 F13 F14 F15 F16 G1 G2 G3 G4 G5 G6 G7 G8 G9 G10 G11 G12 G13 G14 G15 G16 H1 H2 H3 H4 H5 H6 H7 H8 H9 H10 H11 H12 H13 H14 H15 H16 J1 J2 J3 J4 J5 J6 Name SDCKE DD[3] A[1] D[6] VSSRTC BATOK nBATCHG VSSIO D[11] VDDIO PB[1] VDDIO TDO PB[4] PB[6] VSSRTC VSSRTC DD[0] D[3] VSSRTC A[7] A[8] A[9] VSSIO D[12] D[13] PA[7] PA[5] VSSIO PA[4] PA[6] PB[0] PB[2] VSSRTC VSSRTC A[10] A[11] A[12] A[13]/DRA[14] VSSIO D[14] D[15] PA[3] PA[1] VSSIO PA[2] PA[0] TXD[1] Type O O O I/O Description SDRAM clock enable output LCD serial display data System byte address Data I/O Table V. 256-Ball PBGA Ball Listing (Continued) Ball Location J7 J8 J9 J10 J11 J12 J13 J14 J15 J16 K1 K2 K3 K4 K5 K6 K7 K8 K9 K10 K11 K12 K13 K14 K15 K16 L1 L2 L3 L4 L5 L6 L7 L8 L9 L10 L11 L12 L13 L14 L15 L16 M1 M2 M3 M4 M5 M6 Name CTS VSSRTC VSSRTC A[17]/DRA[10] A[16]/DRA[11] A[15]/DRA[12] A[14]/DRA[13] nTRST D[16] D[17] LEDDRV PHDIN VSSIO DCD nTEST[1] EINT[3] VSSRTC ADCIN COL[4] TCLK D[20] D[19] D[18] VSSIO VDDIO VDDIO RXD[1] DSR VDDIO nEINT[1] PE[2]/CLKSEL VSSRTC PD[0]/LEDFLSH VSSRTC COL[6] D[31] VSSRTC A[22]/DRA[5] A[21]/DRA[6] VSSIO A[18]/DRA[9] A[19]/DRA[8] nTEST[0] nEINT[2] VDDIO PE[0]/BOOTSEL[0] TMS VDDIO Type I Description UART 1 clear to send input RTC ground Real time clock ground RTC ground Real time clock ground O O O O I I/O I/O O I System byte address / SDRAM address System byte address / SDRAM address System byte address / SDRAM address System byte address / SDRAM address JTAG async reset input Data I/O Data I/O IR LED drivet Photodiode input RTC ground Real time clock ground I I Battery ok input Battery changed sense input Pad ground I/O ground I/O Pad power I Pad power O I I Data I/O Digital I/O power, 3.3V GPIO port B Digital I/O power, 3.3V JTAG data out GPIO port B GPIO port B Pad ground I/O ground I I I UART 1 data carrier detect Test mode select input External interrupt Core ground Real time clock ground RTC ground Real time clock ground O I/O LCD serial display data Data I/O RTC ground Real time clock ground I O I I/O I/O I/O SSI1 ADC serial input Keyboard scanner column drive JTAG clock Data I/O Data I/O Data I/O RTC ground Real time clock ground O O O System byte address System byte address System byte address Pad ground I/O ground I/O I/O I I Data I/O Data I/O GPIO port A GPIO port A Pad ground I/O ground Pad power Pad power I I Pad power I I Digital I/O power, 3.3V Digital I/O power, 3.3V UART 1 receive data input UART 1 data set ready input Digital I/O power, 3.3V External interrupt input GPIO port E / clock input mode select Pad ground I/O ground I I I I GPIO port A GPIO port A GPIO port B GPIO port B RTC ground Real time clock ground I/O GPIO port D / LED blinker output RTC ground Real time clock ground RTC ground Real time clock ground O O O O System byte address System byte address System byte address System byte address / SDRAM address Core ground Real time clock ground O I/O Keyboard scanner column drive Data I/O RTC ground Real time clock ground O O System byte address / SDRAM address System byte address / SDRAM address Pad ground I/O ground I/O I/O I I Data I/O Data I/O GPIO port A GPIO port A Pad ground I/O ground O O I I Pad power I I Pad power System byte address / SDRAM address System byte address / SDRAM address Test mode select input External interrupt input Digital I/O power, 3.3V GPIO port E / Boot mode select JTAG mode select Digital I/O power, 3.3V Pad ground I/O ground I I O GPIO port A GPIO port A UART 1 transmit data out DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 47 EP7311 High-Performance, Low-Power System on Chip Table V. 256-Ball PBGA Ball Listing (Continued) Ball Location M7 M8 M9 M10 M11 M12 M13 M14 M15 M16 N1 N2 N3 N4 N5 N6 N7 N8 N9 N10 N11 N12 N13 N14 N15 N16 P1 P2 P3 P4 P5 P6 P7 P8 P9 P10 P11 P12 P13 P14 P15 P16 R1 R2 R3 R4 R5 R6 Name SSITXFR DRIVE[1] FB[0] COL[0] D[27] VSSIO A[23]/DRA[4] VDDIO A[20]/DRA[7] D[21] nEXTFIQ PE[1]/BOOTSEL[1] VSSIO VDDIO PD[5] PD[2] SSIRXDA ADCCLK SMPCLK COL[2] D[29] D[26] HALFWORD VSSIO D[22] D[23] VSSRTC RTCOUT VSSIO VSSIO VDDIO VSSIO VSSIO VDDIO VSSIO VDDIO VSSIO VSSIO VDDIO VSSIO D[24] VDDIO RTCIN VDDIO PD[4] PD[1] SSITXDA nADCCS Type I/O I/O I O I/O Description MCP/CODEC/SSI2 frame sync PWM drive output PWM feedback input Keyboard scanner column drive Data I/O Table V. 256-Ball PBGA Ball Listing (Continued) Ball Location R7 R8 R9 R10 R11 R12 R13 R14 R15 R16 T1 T2 T3 T4 T5 T6 T7 T8 T9 T10 T11 T12 T13 T14 T15 T16 Name VDDIO ADCOUT COL[7] COL[3] COL[1] D[30] A[27]/DRA[0] A[25]/DRA[2] VDDIO A[24]/DRA[3] VDDRTC PD[7]/SDQM[1] PD[6]/SDQM[0] PD[3] SSICLK SSIRXFR VDDCORE DRIVE[0] FB[1] COL[5] VDDIO BUZ D[28] A[26]/DRA[1] D[25] VSSIO Type Pad power O O O O I/O O O Pad power O RTC power I/O I/O I/O I/O - Description Digital I/O power, 3.3V SSI1 ADC serial data output Keyboard scanner column drive Keyboard scanner column drive Keyboard scanner column drive Data I/O System byte address / SDRAM address System byte address / SDRAM address Digital I/O power, 3.3V System byte address / SDRAM address Real time clock power, 2.5V GPIO port D / SDRAM byte lane mask GPIO port D / SDRAM byte lane mask GPIO port D MCP/CODEC/SSI2 serial clock MCP/CODEC/SSI2 frame sync Pad ground I/O ground O Pad power O I/O I I System byte address / SDRAM address Digital I/O power, 3.3V System byte address / SDRAM address Data I/O External fast interrupt input GPIO port E / boot mode select Pad ground I/O ground Pad power I/O I/O I/O O O O I/O I/O O Digital I/O power, 3.3V GPIO port D GPIO port D MCP/CODEC/SSI2 serial data input SSI1 ADC serial clock SSI1 ADC sample clock Keyboard scanner column drive Data I/O Data I/O Halfword access select output Core power Core power, 2.5V I/O I O Pad power O I/O O I/O PWM drive output PWM feedback input Keyboard scanner column drive Digital I/O power, 3.3V Buzzer drive output Data I/O System byte address / SDRAM address Data I/O Pad ground I/O ground I/O I/O Data I/O Data I/O Pad ground I/O ground RTC ground Real time clock ground O Real time clock oscillator output Pad ground I/O ground Pad ground I/O ground Pad power Digital I/O power, 3.3V Pad ground I/O ground Pad ground I/O ground Pad power Digital I/O power, 3.3V Pad ground I/O ground Pad power Digital I/O power, 3.3V Pad ground I/O ground Pad ground I/O ground Pad power Digital I/O power Pad ground I/O ground I/O Pad power I/O Pad power I/O I/O O O Data I/O Digital I/O power, 3.3V Real time clock oscillator input Digital I/O power, 3.3V GPIO port D GPIO port D MCP/CODEC/SSI2 serial data output SSI1 ADC chip select 48 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip JTAG Boundary Scan Signal Ordering Table W. JTAG Boundary Scan Signal Ordering LQFP Pin No. 1 4 5 6 7 8 9 10 13 14 15 16 17 18 19 20 23 24 25 26 27 28 29 30 31 32 34 35 36 37 38 39 40 41 42 43 TFBGA Ball B3 A2 B1 E3 C1 C2 E2 D2 F3 D1 F2 G3 E1 F1 G2 G1 H3 H1 J3 J2 J1 L3 K2 K1 M3 L2 L1 N3 M2 M1 P3 N1 N2 R3 P1 P2 PBGA Ball B1 C2 E4 D1 F5 D2 F4 E1 E2 G5 F1 G4 F2 H7 G1 H6 H1 H5 H2 H4 J1 J4 J2 J5 K1 J6 K2 J7 L1 K4 L2 K5 M1 K6 M2 L4 Signal nCS[5] EXPCLK WORD WRITE/nSDRAS RUN/CLKEN EXPRDY TXD2 RXD2 PB[7] PB[6] PB[5] PB[4] PB[3] PB[2] PB[1]/PRDY2 PB[0]/PRDY1 PA[7] PA[6] PA[5] PA[4] PA[3] PA[2] PA[1] PA[0] LEDDRV TXD1 PHDIN CTS RXD1 DCD DSR nTEST1 nTEST0 EINT3 nEINT2 nEINT1 Type O I/O O O O I O I I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O O O I I I I I I I I I I Position 1 3 6 8 10 13 14 16 17 20 23 26 29 32 35 38 41 44 47 50 53 56 59 62 65 67 69 70 71 72 73 74 75 76 77 78 DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 49 EP7311 High-Performance, Low-Power System on Chip Table W. JTAG Boundary Scan Signal Ordering (Continued) LQFP Pin No. 44 45 46 47 53 54 55 56 59 60 61 62 68 69 70 75 76 77 78 79 80 82 83 84 85 86 87 88 91 92 93 94 95 96 97 99 100 101 TFBGA Ball T3 R1 R2 T1 T2 V4 W4 Y4 V5 W5 Y5 V6 W6 Y6 W8 Y8 V9 W10 Y10 V11 W11 Y11 Y12 W12 V12 Y13 W13 V13 Y14 W14 A1 V14 Y15 W15 V15 Y16 W16 V16 PBGA Ball N1 L5 N2 M4 T2 T3 N5 R3 T4 N6 R4 L7 T6 K8 R6 M8 T8 N8 R8 N9 T9 M9 R9 L9 T10 K9 R10 N10 R11 M10 T12 L10 R12 N11 T13 R13 M11 T14 Signal nEXTFIQ PE[2]/CLKSEL PE[1]/BOOTSEL1 PE[0]/BOOTSEL0 PD[7]/SDQM[1] PD[6/SDQM[0]] PD[5] PD[4] PD[3] PD[2] PD[1] PD[0]/LEDFLSH SSIRXFR ADCIN nADCCS DRIVE1 DRIVE0 ADCCLK ADCOUT SMPCLK FB1 FB0 COL7 COL6 COL5 COL4 COL3 COL2 COL1 COL0 BUZ D[31] D[30] D[29] D[28] A[27]/DRA[0] D[27] A[26]/DRA[1] Type I I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O O I/O I O I/O I/O O O O I I O O O O O O O O O I/O I/O I/O I/O Out I/O O Position 79 80 83 86 89 92 95 98 101 104 107 110 122 125 126 128 131 134 136 138 140 141 142 144 146 148 150 152 154 156 158 160 163 166 169 172 174 177 50 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Table W. JTAG Boundary Scan Signal Ordering (Continued) LQFP Pin No. 102 103 104 105 106 109 110 111 112 113 114 115 117 118 119 120 121 122 126 127 128 129 130 131 132 133 134 135 136 137 138 141 142 143 144 145 146 147 TFBGA Ball Y17 W17 Y18 V17 W18 Y19 W20 U18 V20 U19 U20 T19 T20 R19 R20 T18 P19 P20 R18 N19 N20 P18 M19 N18 L20 L19 M18 K20 K19 K18 J20 J19 H20 H19 J18 K3 Y3 G20 PBGA Ball N12 R14 T15 N13 R16 P15 M13 N16 L12 N15 L13 M16 M15 K11 L16 K12 L15 K13 J10 J16 J11 J15 J12 H16 J13 H15 H13 G16 H12 G15 H11 F15 H10 E16 G13 E15 G12 D16 Signal D[26] A[25]/DRA[2] D[25] HALFWORD A[24]/DRA[3] D[24] A[23]/DRA[4] D[23] A[22]/DRA[5] D[22] A[21]/DRA[6] D[21] A[20]/DRA[7] D[20] A[19]/DRA[8] D[19] A[18]/DRA[9] D[18] A[17]/DRA[10] D[17] A[16]/DRA[11] D[16] A[15]/DRA[12] D[15] A[14]/DRA[13] D[14] A[13]/DRA[14] D[13] A[12] D[12] A[11] D[11] A[10] D[10] A[9] D[9] A[8] D[8] Type I/O O I/O O O I/O O I/O O I/O O I/O O I/O O I/O O I/O O I/O O I/O O I/O O I/O O I/O O I/O O I/O O I/O O I/O O I/O Position 179 182 184 187 189 191 194 196 199 201 204 206 209 211 214 216 219 221 224 226 229 231 234 236 239 241 244 246 249 251 254 256 259 261 264 266 269 271 DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 51 EP7311 High-Performance, Low-Power System on Chip Table W. JTAG Boundary Scan Signal Ordering (Continued) LQFP Pin No. 148 150 151 152 153 154 155 156 161 162 163 164 165 166 169 170 171 172 173 175 176 177 178 179 184 185 186 187 188 189 191 192 193 194 195 196 199 200 TFBGA Ball H18 F20 G19 E20 F19 G18 D20 F18 D19 E19 C19 C20 E18 B20 B16 A16 C15 B15 A15 C14 B14 A14 C13 B13 A13 C12 B12 A12 C11 B11 B10 A10 A9 B9 C9 A8 B8 C8 PBGA Ball G11 D15 F13 C16 F12 C15 E13 B16 B14 D11 A13 F10 B13 E10 B12 D10 A11 G9 B11 A10 F9 B10 E9 A9 D8 B8 E8 A7 F8 B7 A6 G8 B6 D7 A5 E7 F7 A4 Signal A[7] D[7] nBATCHG nEXTPWR BATOK nPOR nMEDCHG/nBROM nURESET WAKEUP nPWRFL A[6] D[6] A[5] D[5] A[4] D[4] A[3] D[3] A[2] D[2] A[1] D[1] A[0] D[0] CL2 CL1 FRM M DD[3] DD[2] DD[1] DD[0] nSDCS[1] nSDCS[0] SDQM[3] SDQM[2] SDCKE SDCLK Type O I/O I I I I I I I I O I/O O I/O O I/O O I/O O I/O O I/O O I/O O O O O I/O I/O I/O I/O O O I/O I/O I/O I/O Position 274 276 279 280 281 282 283 284 285 286 287 289 292 294 297 299 302 304 307 309 312 314 317 319 322 324 326 328 330 333 336 339 342 344 346 349 352 355 52 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Table W. JTAG Boundary Scan Signal Ordering (Continued) LQFP Pin No. 201 202 204 205 206 207 208 TFBGA Ball A7 B7 C7 A6 B6 C6 A5 PBGA Ball D6 B4 E6 A3 D5 B3 A2 Signal nMWE/nSDWE nMOE/nSDCAS nCS[0] nCS[1] nCS[2] nCS[3] nCS[4] Type O O O O O O O Position 358 360 362 364 366 368 370 1) See EP7311 Users' Manual for pin naming / functionality. 2) For each pad, the JTAG connection ordering is input, output, then enable as applicable. DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 53 EP7311 High-Performance, Low-Power System on Chip CONVENTIONS This section presents acronyms, abbreviations, units of measurement, and conventions used in this data sheet. Table X. Acronyms and Abbreviations (Continued) Acronym/ Abbreviation TAP TLB Definition test access port translation lookaside buffer universal asynchronous receiver Acronyms and Abbreviations Table X lists abbreviations and acronyms used in this data sheet. Table X. Acronyms and Abbreviations UART Units of Measurement Table Y. Unit of Measurement Acronym/ Abbreviation A/D ADC CODEC D/A DMA EPB FCS FIFO FIQ GPIO ICT IR IRQ IrDA JTAG LCD LED LQFP LSB MIPS MMU MSB PBGA PCB PDA PLL p/u RISC RTC SIR SRAM SSI Definition analog-to-digital analog-to-digital converter coder / decoder digital-to-analog direct-memory access embedded peripheral bus frame check sequence first in / first out fast interrupt request general purpose I/O in circuit test infrared standard interrupt request Infrared Data Association Joint Test Action Group liquid crystal display light-emitting diode low profile quad flat pack least significant bit millions of instructions per second memory management unit most significant bit plastic ball grid array printed circuit board personal digital assistant phase locked loop pull-up resistor reduced instruction set computer Real-Time Clock slow (9600-115.2 kbps) infrared static random access memory synchronous serial interface Symbol Unit of Measure degree Celsius sample frequency hertz (cycle per second) kilobits per second kilobyte (1,024 bytes) kilohertz kilohm megabits (1,048,576 bits) per second megabyte (1,048,576 bytes) megabytes per second megahertz (1,000 kilohertz) microampere microfarad microwatt microsecond (1,000 nanoseconds) milliampere milliwatt millisecond (1,000 microseconds) nanosecond volt watt C fs Hz kbps KB kHz k Mbps MB MBps MHz A F W s mA mW ms ns V W 54 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip General Conventions Hexadecimal numbers are presented with all letters in uppercase and a lowercase "h" appended or with a 0x at the beginning. For example, 0x14 and 03CAh are hexadecimal numbers. Binary numbers are enclosed in single quotation marks when in text (for example, `11' designates a binary number). Numbers not indicated by an "h", 0x or quotation marks are decimal. Registers are referred to by acronym, with bits listed in brackets separated by a colon (:) (for example, CODR[7:0]), and are described in the EP7311 User's Manual. The use of "TBD" indicates values that are "to be determined," "n/a" designates "not available," and "n/c" indicates a pin that is a "no connect." Pin Description Conventions Abbreviations used for signal directions are listed in Table Z. Table Z. Pin Description Conventions Abbreviation I O I/O Input Output Input or Output Direction DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 55 EP7311 High-Performance, Low-Power System on Chip Ordering Information Model Temperature Package EP7311-CB EP7311-CB-90 (90 MHz) EP7311-IB EP7311-IB-90 (90 MHz) EP7311-CV EP7311-IV EP7311-CR EP7311-CR-90 (90 MHz) 0 to +70 C 256-pin PBGA, 17mm X 17mm -40 to +85 C. 0 to +70 C -40 to +85 C. 0 to +70 C 208-pin LQFP. 204-pin TFBGA, 13mm X 13mm. Environmental, Manufacturing, & Handling Information Model Number Peak Reflow Temp MSL Rating* Max Floor Life EP7311-CB EP7311-CB-90 (90 MHz) EP7311-IB EP7311-IB-90 (90 MHz) EP7311-CV EP7311-IV EP7311-CR EP7311-CR-90 (90 MHz) 225 C 3 7 Days * MSL (Moisture Sensitivity Level) as specified by IPC/JEDEC J-STD-020. 56 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 EP7311 High-Performance, Low-Power System on Chip Revision History Revision PP1 F1 Date NOV 2003 AUG 2005 First preliminary release. Updated SDRAM timing. Added MSL data. Changes Contacting Cirrus Logic Support For all product questions and inquiries contact a Cirrus Logic Sales Representative. To find the one nearest to you go to www.cirrus.com IMPORTANT NOTICE Cirrus Logic, Inc. and its subsidiaries ("Cirrus") believe that the information contained in this document is accurate and reliable. However, the information is subject to change without notice and is provided "AS IS" without warranty of any kind (express or implied). Customers are advised to obtain the latest version of relevant information to verify, before placing orders, that information being relied on is current and complete. All products are sold subject to the terms and conditions of sale supplied at the time of order acknowledgment, including those pertaining to warranty, indemnification, and limitation of liability. No responsibility is assumed by Cirrus for the use of this information, including use of this information as the basis for manufacture or sale of any items, or for infringement of patents or other rights of third parties. This document is the property of Cirrus and by furnishing this information, Cirrus grants no license, express or implied under any patents, mask work rights, copyrights, trademarks, trade secrets or other intellectual property rights. Cirrus owns the copyrights associated with the information contained herein and gives consent for copies to be made of the information only for use within your organization with respect to Cirrus integrated circuits or other products of Cirrus. This consent does not extend to other copying such as copying for general distribution, advertising or promotional purposes, or for creating any work for resale. CERTAIN APPLICATIONS USING SEMICONDUCTOR PRODUCTS MAY INVOLVE POTENTIAL RISKS OF DEATH, PERSONAL INJURY, OR SEVERE PROPERTY OR ENVIRONMENTAL DAMAGE ("CRITICAL APPLICATIONS"). CIRRUS PRODUCTS ARE NOT DESIGNED, AUTHORIZED OR WARRANTED FOR USE IN AIRCRAFT SYSTEMS, MILITARY APPLICATIONS, PRODUCTS SURGICALLY IMPLANTED INTO THE BODY, AUTOMOTIVE SAFETY OR SECURITY DEVICES, LIFE SUPPORT PRODUCTS OR OTHER CRITICAL APPLICATIONS. INCLUSION OF CIRRUS PRODUCTS IN SUCH APPLICATIONS IS UNDERSTOOD TO BE FULLY AT THE CUSTOMER'S RISK AND CIRRUS DISCLAIMS AND MAKES NO WARRANTY, EXPRESS, STATUTORY OR IMPLIED, INCLUDING THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR PARTICULAR PURPOSE, WITH REGARD TO ANY CIRRUS PRODUCT THAT IS USED IN SUCH A MANNER. IF THE CUSTOMER OR CUSTOMER'S CUSTOMER USES OR PERMITS THE USE OF CIRRUS PRODUCTS IN CRITICAL APPLICATIONS, CUSTOMER AGREES, BY SUCH USE, TO FULLY INDEMNIFY CIRRUS, ITS OFFICERS, DIRECTORS, EMPLOYEES, DISTRIBUTORS AND OTHER AGENTS FROM ANY AND ALL LIABILITY, INCLUDING ATTORNEYS' FEES AND COSTS, THAT MAY RESULT FROM OR ARISE IN CONNECTION WITH THESE USES. Cirrus Logic, Cirrus, and the Cirrus Logic logo designs are trademarks of Cirrus Logic, Inc. All other brand and product names in this document may be trademarks or service marks of their respective owners. SPI is a trademark of Motorola, Inc. Microwire is a trademark of National Semiconductor Corporation. LINUX is a registered trademark of Linus Torvalds. Microsoft Windows and Microsoft are registered trademarks of Microsoft Corporation. DS506F1 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) 57 EP7311 High-Performance, Low-Power System on Chip 58 (c)Copyright Cirrus Logic, Inc. 2005 (All Rights Reserved) DS506F1 |
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