a DSP Microcomputer ADSP-2192M ADSP-2192M DUAL CORE DSP FEATURES 320 MIPS ADSP-219x DSP in a 144-Lead LQFP Package with PCI, USB, Sub-ISA, and CardBus Interfaces 3.3 V/5.0 V PCI 2.2 Compliant 33 MHz/32-bit Interface with Bus Mastering over Four DMA Channels with Scatter-Gather Support Integrated USB 1.1 Compliant Interface Sub-ISA Interface AC’97 Revision 2.1 Compliant Interface for External Audio, Modem, and Handset Codecs with DMA Capability Dual ADSP-219x Core Processors (P0 and P1) on Each ADSP-2192M DSP Chip 132K Words of Memory Includes 4K 16-Bit Shared Data Memory 80K Words of On-Chip RAM on P0, Configured as 64K Words On-Chip 16-Bit RAM for Data Memory and 16K Words On-Chip 24-Bit RAM for Program Memory 48K Words of On-Chip RAM on P1, Configured as 32K Words On-Chip 16-Bit RAM for Data Memory and 16K Words On-Chip 24-Bit RAM for Program Memory 4K Words of Additional On-Chip RAM Shared by Both Cores, Configured as 4K Words On-Chip 16-Bit RAM Flexible Power Management with Selectable PowerDown and Idle Modes Programmable PLL Supports Frequency Multiplication, Enabling Full Speed Operation from Low Speed Input Clocks 2.5 V Internal Operation Supports 3.3 V/5.0 V Compliant I/O FUNCTIONAL BLOCK DIAGRAM P0 MEMORY P1 MEMORY SHARED MEMORY 16K24 PM 64K16 DM BOOT ROM ADDR DATA 16K24 PM 32K16 DM BOOT ROM ADDR DATA 4K16 DM ADDR DATA ADSP-219x DSP CORE ADSP-219x DSP CORE (SEE FIGURE 1 ON PAGE 3) (SEE FIGURE 1 ON PAGE 3) CORE INTERFACE PROCESSOR P0 CORE INTERFACE ADDR DATA ADDR DATA ADDR DATA P0 DMA CONTROLLER FIFOS GP I/O PINS (AND OPTIONAL SERIAL EEPROM) PROCESSOR P1 P1 DMA CONTROLLER SHARED DSP I/O MAPPED REGISTERS SERIAL PORT AC'97 COMPLIANT FIFOS HOST PORT PCI 2.2 OR USB 1.1 JTAG EMULATION PORT REV. 0 Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective companies. One Technology Way, P.O.Box 9106, Norwood, MA 02062-9106, U.S.A. Tel:781/329-4700 www.analog.com Fax:781/326-8703 © 2002 Analog Devices, Inc. All rights reserved. ADSP-2192M ADSP-2192M DUAL CORE DSP FEATURES (continued) Eight Dedicated General-Purpose I/O Pins with Integrated Interrupt Support Each DSP Core Has a Programmable 32-Bit Interval Timer Five DMA Channels Available on Each Core Boot Methods Include Booting Through PCI Port, USB Port, or Serial EEPROM JTAG Test Access Port Supports On-Chip Emulation and System Debugging 144-Lead LQFP Package TABLE OF CONTENTS GENERAL DESCRIPTION . . . . . . . . . . . . . . . . . . . . 3 DSP Core Architecture . . . . . . . . . . . . . . . . . . . . . . . 3 DSP Peripherals . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 Memory Architecture . . . . . . . . . . . . . . . . . . . . . . . . 4 Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 DMA Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 External Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . 6 Internal Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 Register Spaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 CardBus Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 Using the PCI Interface . . . . . . . . . . . . . . . . . . . . . . . 7 Using the USB Interface . . . . . . . . . . . . . . . . . . . . . 13 General USB Device Definitions . . . . . . . . . . . . . . . 17 Sub-ISA Interface . . . . . . . . . . . . . . . . . . . . . . . . . . 21 PCI Interface to DSP Memory . . . . . . . . . . . . . . . . 22 USB Interface to DSP Memory . . . . . . . . . . . . . . . . 22 AC’97 Codec Interface to DSP Memory . . . . . . . . . 22 Data FIFO Architecture . . . . . . . . . . . . . . . . . . . . . 22 System Reset Description . . . . . . . . . . . . . . . . . . . . 23 Power Management Description . . . . . . . . . . . . . . . 24 Power Regulators . . . . . . . . . . . . . . . . . . . . . . . . . . 24 2.5 V Regulator Options . . . . . . . . . . . . . . . . . . . . . 24 Low Power Operation . . . . . . . . . . . . . . . . . . . . . . . 25 Clock Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 Instruction Set Description . . . . . . . . . . . . . . . . . . . 26 Development Tools . . . . . . . . . . . . . . . . . . . . . . . . . 26 Additional Information . . . . . . . . . . . . . . . . . . . . . . 28 PIN DESCRIPTIONS . . . . . . . . . . . . . . . . . . . . . . . . 28 SPECIFICATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . 30 ABSOLUTE MAXIMUM RATINGS . . . . . . . . . . 31 ESD SENSITIVITY . . . . . . . . . . . . . . . . . . . . . . . . 31 TIMING SPECIFICATIONS . . . . . . . . . . . . . . . . 31 Output Drive Currents . . . . . . . . . . . . . . . . . . . . . . 34 Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Test Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Environmental Conditions . . . . . . . . . . . . . . . . . . . 35 144-Lead LQFP Pinout . . . . . . . . . . . . . . . . . . . . . 36 OUTLINE DIMENSIONS . . . . . . . . . . . . . . . . . . . . 38 ORDERING GUIDE . . . . . . . . . . . . . . . . . . . . . . . . 38 DSP CORE FEATURES 6.25 ns Instruction Cycle Time (Internal), for up to 160 MIPS Sustained Performance ADSP-218x Family Code Compatible with the Same Easy to Use Algebraic Syntax Single-Cycle Instruction Execution Dual Purpose Program Memory for Both Instruction and Data Storage Fully Transparent Instruction Cache Allows Dual Operand Fetches in Every Instruction Cycle Unified Memory Space Permits Flexible Address Generation, Using Two Independent DAG Units Independent ALU, Multiplier/Accumulator, and Barrel Shifter Computational Units with Dual 40-Bit Accumulators Single-Cycle Context Switch between Two Sets of Computational and DAG Registers Parallel Execution of Computation and Memory Instructions Pipelined Architecture Supports Efficient Code Execution at Speeds up to 160 MIPS Register File Computations with All Nonconditional, Nonparallel Computational Instructions Powerful Program Sequencer Provides Zero-Overhead Looping and Conditional Instruction Execution Architectural Enhancements for Compiled C/C++ Code Efficiency Architecture Enhancements beyond ADSP-218x Family are Supported with Instruction Set Extensions for Added Registers, Ports, and Peripherals –2– REV. 0 ADSP-2192M GENERAL DESCRIPTION The ADSP-2192M’s flexible architecture and comprehensive instruction set support multiple operations in parallel. For example, in one processor cycle, each DSP core within the ADSP-2192M can: The ADSP-2192M is a single-chip microcomputer optimized for digital signal processing (DSP) and other high speed numeric processing applications, and is ideally suited for PC peripherals. • Generate an address for the next instruction fetch The ADSP-2192M combines the ADSP-219x family base architecture (three computational units, two data address generators and a program sequencer) into a chip with two core processors (see the Functional Block Diagram on Page 1 and Figure 1). • Fetch the next instruction • Perform one or two data moves • Update one or two data address pointers • Perform a computational operation DSP CORE These operations take place while the processor continues to: CACHE 64 24-BIT DAG1 4 4 16 DAG2 4 4 16 • Receive and/or transmit data through the Host port (PCI or USB interfaces) PROGRAM SEQUENCER • Receive or transmit data through the AC’97 PM ADDRESS BUS 24 • Decrement the two timers DM ADDRESS BUS 24 DSP Core Architecture BUS CONNECT (PX) PM DATA BUS 24 DM DATA BUS 16 The ADSP-219x architecture is code compatible with the ADSP218x DSP family. Though the architectures are compatible, the ADSP-219x architecture has many enhancements over the ADSP-218x architecture. The enhancements to computational units, data address generators, and program sequencer make the ADSP-219x more flexible and more compiler friendly. CORE INTERFACE DATA REGISTER FILE Indirect addressing options provide addressing flexibility: base address registers for easier implementation of circular buffering, pre-modify with no update, post-modify with update, pre- and post-modify by an immediate 8-bit, twos-complement value. INPUT REGISTERS RESULT REGISTERS MULT 16 16-BIT BARREL SHIFTER The ADSP-219x instruction set provides flexible data moves and multifunction (one or two data moves with a computation) instructions. Every single-word instruction can be executed in a single processor cycle. The ADSP-219x assembly language uses an algebraic syntax for ease of coding and readability. A comprehensive set of development tools supports program development. ALU The Functional Block Diagram on Page 1 shows the architecture of the ADSP-219x dual core DSP, while the block diagram of Figure 1 illustrates the ADSP-219x DSP core. Each core contains three independent computational units: the multiplier/accumulator (MAC), the ALU, and the shifter. The computational units process 16-bit data from the register file and have provisions to support multiprecision computations. The ALU performs a standard set of arithmetic and logic operations; division primitives are also supported. The MAC performs single-cycle multiply, multiply/add, and multiply/subtract operations. The MAC has two 40-bit accumulators that help with overflow. The shifter performs logical and arithmetic shifts, normalization, denormalization, and derive exponent operations. The shifter can be used to efficiently implement numeric format control, including multiword and block floating-point representations. Figure 1. ADSP-219x DSP Core The ADSP-2192M includes a PCI-compatible port, a USBcompatible port, an AC’97-compatible port, a DMA controller, a programmable timer, general-purpose Programmable Flag pins, extensive interrupt capabilities, and on-chip program and data memory spaces. The ADSP-2192M integrates 132K words of on-chip memory configured as 32K words (24-bit) of program RAM, and 100K words (16-bit) of data RAM. power-down circuitry is also provided to reduce power consumption. The ADSP-2192M is available in a 144-lead LQFP package. Fabricated in a high speed, low power, CMOS process, the ADSP-2192M operates with a 6.25 ns instruction cycle time (320 MIPS) using both cores. All instructions can execute in a single DSP cycle. REV. 0 Register-usage rules influence placement of input and results within the computational units. For most operations, the computational units’ data registers act as a data register file, permitting any input or result register to provide input to any unit for a computation. For feedback operations, the computational units let the output (result) of any unit be input to any unit on –3– ADSP-2192M the next cycle. For conditional or multifunction instructions, there are restrictions on which data registers may provide inputs or receive results from each computational unit. For more information, see the ADSP-219x DSP Instruction Set Reference. The programmable interval timer generates periodic interrupts. A 16-bit count register (TCOUNT) is decremented every n cycles where n-1 is a scaling value stored in a 16-bit register (TSCALE). When the value of the count register reaches zero, an interrupt is generated and the count register is reloaded from a 16-bit period register (TPERIOD). A powerful program sequencer controls the flow of instruction execution. The sequencer supports conditional jumps, subroutine calls, and low interrupt overhead. With internal loop counters and loop stacks, the ADSP-219x core executes looped code with zero overhead; no explicit jump instructions are required to maintain loops. Memory Architecture The ADSP-2192M provides 132K words of on-chip SRAM memory. This memory is divided into Program and Data Memory blocks in each DSP’s memory map. In addition to the internal memory space, the two cores can address two additional and separate off-core memory spaces: I/O space and shared memory space, as shown in Figure 2. Two data address generators (DAGs) provide addresses for simultaneous dual operand fetches. Each DAG maintains and updates four 16-bit address pointers. Whenever the pointer is used to access data (indirect addressing), it is pre- or postmodified by the value of one of four possible modify registers. A length value and base address may be associated with each pointer to implement automatic modulo addressing for circular buffers. Page registers in the DAGs allow linear or circular addressing within 64K word boundaries of each of the memory pages, but these buffers may not cross page boundaries. Secondary registers duplicate all the primary registers in the DAGs; switching between primary and secondary registers provides a fast context switch. The ADSP-2192M’s two cores can access 80K and 48K locations that are accessible through two 24-bit address buses, the PMA and DMA buses.The DSP has three functions that support access to the full memory map. • The DAGs generate 24-bit addresses for data fetches from the entire DSP memory address range. Because DAG index (address) registers are 16 bits wide and hold the lower 16 bits of the address, each of the DAGs has its own 8-bit page register (DMPGx) to hold the most significant eight address bits. Before a DAG generates an address, the program must set the DAG’s DMPGx register to the appropriate memory page. Efficient data transfer in the core is achieved with the use of internal buses: • Program Memory Address (PMA) Bus • The Program Sequencer generates the addresses for instruction fetches. For relative addressing instructions, the program sequencer bases addresses for relative jumps, calls, and loops on the 24-bit Program Counter (PC). In direct addressing instructions (two-word instructions), the instruction provides an immediate 24-bit address value. The PC allows linear addressing of the full 24-bit address range. • Program Memory Data (PMD) Bus • Data Memory Address (DMA) Bus • Data Memory Data (DMD) Bus Program memory can store both instructions and data, permitting the ADSP-219x to fetch two operands in a single cycle, one from program memory and one from data memory. The DSP’s dual memory buses also let the ADSP-219x core fetch an operand from data memory and the next instruction from program memory in a single cycle. • For indirect jumps and calls that use a 16-bit DAG address register for part of the branch address, the Program Sequencer relies on an 8-bit Indirect Jump page (IJPG) register to supply the most significant eight address bits. Before a cross page jump or call, the program must set the program sequencer’s IJPG register to the appropriate memory page. DSP Peripherals The Functional Block Diagram on Page 1 shows the DSP’s on-chip peripherals, which include the Host port (PCI or USB), AC’97 port, JTAG test and emulation port, flags, and interrupt controller. Each ADSP-219x DSP core has an on-chip ROM that holds boot routines (See Booting Modes on Page 23.). The ADSP-2192M can respond to up to thirteen interrupts at any given time. A list of these interrupts appears in Table 2. Interrupts The interrupt controller lets the DSP respond to 13 interrupts with minimum overhead. The controller implements an interrupt priority scheme as shown in Table 2. Applications can use the unassigned slots for software and peripheral interrupts. The DSP’s Interrupt Control (ICNTL) register (shown in Table 3) provides controls for global interrupt enable, stack interrupt configuration, and interrupt nesting. The AC’97 Codec port on the ADSP-2192M provides a complete synchronous, full-duplex serial interface. This interface supports the AC’97 standard. The ADSP-2192M provides up to eight general-purpose I/O pins that are programmable as either inputs or outputs. These pins are dedicated general-purpose Programmable Flag pins. –4– REV. 0 ADSP-2192M DSP P0 MEMORY MAP DSP P1 MEMORY MAP ADDRESS SHARED RAM (16 4K) PAGE 2 0x02 0FFF 0x02 0000 ADDRESS SAME SHARED RAM (16 4K) PAGE 2 0x01 FFFF 0x01 FFFF RESERVED RESERVED 0x01 5000 PROGRAM ROM 24 4K PAGE 1 0x01 5000 0x01 4FFF 0x01 4000 PAGE 1 PROGRAM ROM 24 4K 0x01 3FFF PROGRAM RAM (24 16K) 0x01 0000 0x01 0000 0x00 FFFF 0x00 FFFF 0x00 C000 0x00 BFFF DATA RAM BLOCK2 (16 16K) PAGE 0 DATA RAM BLOCK1 (16 16K) SHARED DSP I/O MAPPED REGISTERS RESERVED 0x00 8000 ADDRESS 0x00 7FFF 0xFF FF 0x00 4000 0x00 3FFF DATA RAM BLOCK0 (16 16K) 0x01 4FF F 0x01 4000 0x01 3FF F PROGRAM RAM (24 16K) DATA RAM BLOCK3 (16 16K) 0x02 0FF F 0x02 0000 0x00 8000 PAGE 0 DATA RAM BLOCK1 (16 16K) PAGES 0 255 (16 256) 0x00 4000 0x00 3FF F DATA RAM BLOCK0 (16 16K) 0x00 00 0x00 0000 0x00 7FF F 0x00 0000 Figure 2. ADSP-2192M Internal/External Memory, Boot Memory, and I/O Memory Maps Table 2 shows the interrupt vector and DSP-to-DSP semaphores at reset of each of the peripheral interrupts. The peripheral interrupt’s position in the IMASK and IRPTL register and its vector address depend on its priority level, as shown in Table 2. Table 2. Vector Table Table 1. DSP-to-DSP Semaphores Register Table Flag Bit Direction Function 0 1 2 3 4 5 6 7 8 9 10 11 12 Output Output Output 13 Input 14 15 Input Input DSP–DSP Semaphore 0 DSP–DSP Semaphore 1 DSP–DSP Interrupt Reserved Reserved Reserved Reserved Register Bus Lock DSP–DSP Semaphore 0 DSP–DSP Semaphore 1 DSP–DSP Interrupt Reserved AC’97 Register–PDC Bus Access Status PDC Interface Busy Status (write from DSP pending) Reserved Register Bus Lock Status REV. 0 Output Input Input Input Input Input Bit Priority Interrupt 0 1 1 2 2 3 3 4 5 6 7 8 9 10 11 12 13 14 15 4 5 6 7 8 9 10 11 12 13 14 15 16 Reset (non-maskable) Power-Down (nonmaskable) Kernel interrupt (single step) Stack Status Mailbox Timer GPIO PCI Bus Master DSP–DSP FIFO0 Transmit FIFO0 Receive FIFO1 Transmit FIFO1 Receive Reserved Reserved AC’97 Frame 1 –5– Vector Address Offset1 0x00 0x04 0x08 0x0C 0x10 0x14 0x18 0x1C 0x20 0x24 0x28 0x2C 0x30 0x34 0x38 0x3C The interrupt vector address values are represented as offsets from address 0x01 0000. This address corresponds to the start of Program Memory in DSP P0 and P1. ADSP-2192M Interrupt routines can either be nested with higher priority interrupts taking precedence or processed sequentially. Interrupts can be masked or unmasked with the IMASK register. Individual interrupt requests are logically ANDed with the bits in IMASK; the highest priority unmasked interrupt is then selected. The emulation, power-down, and reset interrupts are nonmaskable with the IMASK register, but software can use the DIS INT instruction to mask the power-down interrupt. External Interfaces Table 3. Interrupt Control (ICNTL) Register Bits PCI 2.2 Host Interface Bit Description 0–3 4 5 6 7 8–9 10 11 12 13–15 Reserved Interrupt nesting enable Global interrupt enable Reserved MAC biased rounding enable Reserved PC stack interrupt enable Loop stack interrupt enable Low power idle enable Reserved Several different interfaces are supported on the ADSP-2192M. These include both internal and external interfaces. The three separate PCI configuration spaces are programmable to set up the device in various Plug-and-Play configurations. The ADSP-2192M provides the following types of external interfaces: PCI, USB, Sub-ISA, CardBus, AC’97, and serial EEPROM. The following sections discuss those interfaces. The ADSP-2192M includes a 33 MHz, 32-bit bus master PCI interface that is compliant with revision 2.2 of the PCI specification. This interface supports the high data rates. USB 1.1 Host Interface The ADSP-2192M USB interface enables the host system to configure and attach a single device with multiple interfaces and various endpoint configurations. The advantages of this design include: • Programmable descriptors and class-specific command interpreter. • An on-chip 8052-compatible MCU allows the user to soft download different configurations and support standard or class-specific commands. The IRPTL register is used to force and clear interrupts. On-chip stacks preserve the processor status and are automatically maintained during interrupt handling. To support interrupt, loop, and subroutine nesting, the PC stack is 33 levels deep, the loop stack is eight levels deep, and the status stack is 16 levels deep. To prevent stack overflow, the PC stack can generate a stack level interrupt if the PC stack falls below three locations full or rises above 28 locations full. • Total of eight user-defined endpoints provided. Endpoints can be configured as either BULK, ISO, or INT, and the endpoints can be grouped and assigned to any interface. Sub-ISA Interface In systems that combine the ADSP-2192M chip with other devices on a single PCI interface, the ADSP-2192M Sub-ISA mode is used to provide a simpler interface that bypasses the ADSP-2192M’s PCI interface. In this mode the Combo Master assumes all responsibility for interfacing the function to the PCI bus, including provision of Configuration Space registers for the ADSP-2192M system as a separate PnP function. In Sub-ISA Mode the PCI Pins are reconfigured for ISA operation. The following instructions globally enable or disable interrupt servicing, regardless of the state of IMASK. ENA INT; DIS INT; At reset, interrupt servicing is disabled. For quick servicing of interrupts, a secondary set of DAG and computational registers exist. Switching between the primary and secondary registers lets programs quickly service interrupts, while preserving the DSP’s state. CardBus Interface The CardBus standard provides higher levels of performance than the 16-bit PC Card standard. For example, 32-bit CardBus cards are able to take advantage of internal bus speeds that can be as much as four to six times faster than 16-bit PC Cards. This design provides for a compact, rugged card that can be completely inserted within its host computer without any external cabling. DMA Controller The ADSP-2192M has a DMA controller that supports automated data transfers with minimal overhead for the DSP core. Cycle stealing DMA transfers can occur between the ADSP-2192M’s internal memory and any of its DMA-capable peripherals. DMA transfers can also be accomplished between any of the DMA-capable peripherals. DMA-capable peripherals include the PCI and AC’97 ports. Each individual DMA-capable peripheral has a dedicated DMA channel. DMA sequences do not contend for bus access with the DSP core; instead, DMAs “steal” cycles to access memory. All DMA transfers use the Program Memory (PMA/PMD) buses shown in the Functional Block Diagram on Page 1. Because CardBus performance attains the same high level as the host platform’s internal (PCI) system bus, it is an excellent way to add high speed communications to the notebook form factor. In addition, CardBus PC Cards operate at a power-saving 3.3 volts, extending battery life in most configurations. This new 32-bit CardBus technology provides up to 132M bytes per second of bandwidth. This performance makes CardBus an ideal vehicle to meet the demands of high throughput communications such as ADSL. –6– REV. 0 ADSP-2192M DSP Core Register Space CardBus PC Cards generate less heat and consume less power. This is attained by: Each DSP has an internal register that is accessible with no latency. These registers are accessible only from within the DSP, using the REG( ) instruction. • Low voltage operation at 3.3 V • Software control of clock speed • Advanced power management mechanism Peripheral Device Control Register Space This Register Space is accessible by both DSPs, the PCI, SubISA, and USB Buses. Note that certain sections of this space are exclusive to either the PCI, USB, or Sub-ISA Buses. These registers control the operation of the peripherals of the ADSP2192M. The DSP accesses these registers using the I/O space instruction. AC’97 2.1 External Codec Interface The industry standard AC’97 serial interface (AC-Link) incorporates a 7-pin digital serial interface that links compliant codecs to the ADSP-2192M. The ACLink implements a bidirectional, fixed rate, serial PCM digital stream. It handles multiple input and output audio streams as well as control and status register accesses using a time division multiplex scheme. USB Register Space These registers control the operation and configuration of the USB Interface. Most of these registers are only accessible via the USB Bus, although a subset is accessible to the DSP. Serial EEPROM Interface The Serial EEPROM for the ADSP-2192M can overwrite the following information which is returned during the USB GET DEVICE DESCRIPTOR command. During the Serial EEPROM initialization procedure, the DSP is responsible for writing the USB Descriptor Vendor ID, USB Descriptor Product ID, USB Descriptor Release Number, and USB Descriptor Device Attributes registers to change the default settings. CardBus Interface The ADSP-2192M’s PC CardBus interface meets the state and timing specifications defined for PCMCIA’s PC CardBus Standard April 1998 Release 6.1. It supports up to three card functions. Multiple function PC cards require a separate set of Configuration registers per function. A primary Card Information Structure common to all functions is required. Separate secondary Card Information Structures, one per function, are also required. Data for each CIS is loaded by the DSP during bootstrap loading. All descriptors can be changed when downloading the RAMbased MCU renumeration code, except for the Manufacturer and Product, which are supported in the CONFIG DEVICE and cannot be overwritten or changed by the Serial EEPROM. • Vendor ID (0x0456) The host PC can read the CIS data at any time. If needed, the WAIT control can be activated to extend the read operation to meet bus write access to the CIS data. • Product ID (0x2192) • Device Release Number (0x0100) • Device Attributes (0x80FA): SP (1 = self-powered, 0 = bus-powered, default = 0); RW (1 = have remote wake-up capability, 0 = no remote wake-up capability, default = 0); C[7:0] (power consumption from bus expressed in 2 mA units; default = 0xFA 500 mA) Using the PCI Interface The ADSP-2192M includes a 33 MHz, 32-bit PCI interface to provide control and data paths between the part and the host CPU. The PCI interface is compliant with the PCI Local Bus Specification Revision 2.2. The interface supports bus mastering as well as bus target interfaces. The PCI Bus Power Management Interface Specification Revision 1.1 is supported and additional features as needed by PCI designs are included. • Manufacturer (ADI) • Product (ADI Device) Internal Interfaces Target/Slave Interface The ADSP-2192M provides three types of internal interfaces: registers, codec, and DSP memory buses. The following sections discuss those interfaces. The ADSP-2192M PCI interface contains three separate functions, each with its own configuration space. Each function contains four base address registers used to access ADSP-2192M control registers and DSP memory. Base Address Register (BAR) 1 is used to point to the control registers. The addresses specified in these tables are offsets from BAR1 in each of the functions. PCI memory-type accesses are used to read and write the registers. Register Interface The register interface allows the PCI interface, USB interface, and both DSPs to communicate with the I/O Registers. These registers map into DSP, PCI, and USB I/O spaces. Register Spaces DSP memory accesses use BAR2 or BAR3 of each function. BAR2 is used to access 24-bit DSP memory; BAR3 accesses 16-bit DSP memory. Maps of the BAR2 and BAR3 registers appear in Table 8 on Page 11 and Table 9 on Page 12. Several different register spaces are defined on the ADSP2192M, as described in the following sections. PCI Configuration Space These registers control the configuration of the PCI Interface. Most of these registers are only accessible via the PCI Bus although a subset is accessible to the DSP for configuration during the boot. REV. 0 The lower half of the allocated space pointed to by each DSP memory BAR is the DSP memory for DSP core P0. The upper half is the memory space associated with DSP core P1. PCI transactions to and from DSP memory use the DMA function within the DSP core. Thus each word transferred to or from PCI –7– ADSP-2192M space uses a single DSP clock cycle to perform the internal DSP data transfer. Byte-wide accesses to DSP memory are not supported. To initiate a scatter-gather transfer between memory and the ADSP-2192M, the following steps are involved: 1. Software driver prepares a SGD table in system memory. Each descriptor is eight bytes long and consists of an address pointer to the starting address and the transfer count of the memory buffer to be transferred. In any given SGD table, two consecutive SGDs are offset by eight bytes and are aligned on a 4-byte boundary. Each SGD contains: I/O type accesses are supported via BAR4. Both the control registers accessible via BAR1 and the DSP memory accessible via BAR2 and BAR3 can be accessed with I/O accesses. Indirect access is used to read and write both the control registers and the DSP memory. For the control register accesses, an address register points to the word to be accessed while a separate register is used to transfer the data. Read/write control is part of the address register. Only 16-bit accesses are possible via the I/O space. a. Memory Address (Buffer Start) – 4 bytes b. Byte Count (Buffer Size) – 3 bytes A separate set of registers is used to perform the same function for DSP memory access. Control for these accesses includes a 24-bit/16-bit select as well as direction control. The data register for DSP memory accesses is a full 24 bits wide. 16-bit accesses will be loaded into the lower 16 bits of the register. Table 10 on Page 14 lists the registers directly accessible from BAR4. c. End of Linked List (EOL) – 1 bit (MSBit) d.Flag – 1 bit (MSBit – 1) 2. Initialize DMA control registers with transfer-specific information such as number of total bytes to transfer, direction of transfer, etc. 3. Software driver initializes the hardware pointer to the SGD table. Bus Master Interface As a bus master, the PCI interface can transfer DMA data between system memory and the DSP. The control registers for these transfers are available both to the host and to the DSPs. Four channels of bus mastering DMA are supported on the ADSP-2192M. 4. Engage scatter-gather DMA by writing the start value to the PCI channel Control/Status register. 5. The ADSP-2192M will then pull in samples as pointed to by the descriptors as needed by the DMA engine. When the EOL is reached, a status bit will be set and the DMA will end if the data buffer is not to be looped. If looping is to occur, DMA transfers will continue from the beginning of the table until the channel is turned off. Two channels are associated with the receive data and two are associated with the transmit data. The internal DSPs will typically control initiation of bus master transactions. DMA host bus master transfers can specify either standard circular buffers in system memory or perform scatter-gather DMA to host memory. 6. Bits in the PCI Control/Status register control whether an interrupt occurs when the EOL is reached or when the FLAG bit is set. Each bus master DMA channel includes four registers to specify a standard circular buffer in system memory. The Base Address points to the start of the circular buffer. The Current Address is a pointer to the current position within that buffer. The Base Count specifies the size of the buffer in bytes, while the Current Count keeps track of how many bytes need to be transferred before the end of the buffer is reached. When the end of the buffer is reached, the channel can be programmed to loop back to the beginning and continue the transfers. When this looping occurs, a Status bit will be set in the DMA Control Register. Scatter-gather DMA uses four registers. In scatter-gather mode the functions of the registers are mapped as shown in Table 4. Table 4. Register Mapping in Scatter-Gather Mode The PCI DMA controller can be programmed to perform scatter-gather DMA, when transferring samples to and from DSP memory. This mode allows the data to be split up in memory, and yet be transferable to and from the ADSP-2192M without processor intervention. In scatter-gather mode, the DMA controller can read the memory address and word count from an array of buffer descriptors called the Scatter-Gather Descriptor (SGD) table. This allows the DMA engine to sustain DMA transfers until all buffers in the SGD table are transferred. Standard Circular Buffer Mode Scatter-Gather Mode Function Base Address Current Address SGD Table Pointer SGD Current Pointer Address SGD Pointer Current SGD Count Base Count Current Count In either mode of operation, interrupts can be generated based upon the total number of bytes transferred. Each channel has two 24-bit registers to count the bytes transferred and generate interrupts as appropriate. The Interrupt Base Count register specifies the number of bytes to transfer prior to generating an interrupt. The Interrupt Count register specifies the current number left prior to generating the interrupt. When the Interrupt Count –8– REV. 0 ADSP-2192M Table 6. PCI Control Register register reaches zero, a PCI interrupt can be generated. Also, the Interrupt Count register will be reloaded from the Interrupt Base Count and continue counting down for the next interrupt. Bit Name Comments 1–0 PCI Functions Configured 2 Configuration Ready 00 = One PCI function enabled, 01 = Two functions, 10 = Three functions When 0, disables PCI accesses to the ADSP-2192M (terminated with Retry). Must be set to 1 by DSP ROM code after initializing configuration space. Once 1, cannot be written to 0. 15–3 Reserved Table 5. PCI Interrupt Register Bit Name Comments 0 1 Reserved Rx0 DMA Channel Interrupt Rx1 DMA Channel Interrupt Tx0 DMA Channel Interrupt Tx1 DMA Channel Interrupt Incoming Mailbox 0 PCI Interrupt Incoming Mailbox 1 PCI Interrupt Outgoing Mailbox 0 PCI Interrupt Outgoing Mailbox 1 PCI Interrupt Reserved Reserved I/O Wake-up AC’97 Wake-up PCI Master Abort Interrupt PCI Target Abort Interrupt Reserved Reserve Receive Channel 0 Bus Master Transactions Receive Channel 1 Bus Master Transactions Transmit Channel 0 Bus Master Transactions Transmit Channel 1 Bus Master Transactions PCI to DSP Mailbox 0 Transfer PCI to DSP Mailbox 1 Transfer DSP to PCI Mailbox 0 Transfer DSP to PCI Mailbox 1 Transfer 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Similarities Between the Three PCI Functions Each function contains a complete set of registers in the predefined header region as defined in the PCI Local Bus Specification Revision 2.2. In addition, each function contains the optional registers to support PCI Bus Power Management. Generally, registers that are unimplemented or read-only in one function are similarly defined in the other functions. Each function contains four base address registers that are used to access ADSP-2192M control registers and DSP memory. Base address register (BAR) 1 is used to access the ADSP2192M control registers. Accesses to the control registers via BAR1 uses PCI memory accesses. BAR1 requests a memory allocation of 1024 bytes. Access to DSP memory occurs via BAR2 and BAR3. BAR2 is used to access 24-bit DSP memory (for DSP program downloading) while BAR3 is used to access 16-bit DSP memory. BAR4 provides I/O space access to both the control registers and the DSP memory. I/O Pin Initiated AC’97 Interface Initiated PCI Interface Master Abort Detected PCI Interface Target Abort Detected Table 7 shows the configuration space headers for the three spaces. While these are the default uses for each of the configurations, they can be redefined to support any possible function by writing to the class code register of that function during boot. Additionally, during boot time, the DSP can disable one or more of the functions. If only two functions are enabled, they will be functions 0 and 1. If only one function is enabled, it will be function 0. PCI Interrupts There are a variety of potential sources of interrupts to the PCI host besides the bus master DMA interrupts. A single interrupt pin, INTA is used to signal these interrupts back to the host. The PCI Interrupt Register consolidates all of the possible interrupt sources; the bits of this register are shown in Table 5. The register bits are set by the various sources, and can be cleared by writing a 1 to the bit(s) to be cleared. Interactions Between the Three PCI Configurations Because the configurations must access and control a single set of resources, potential conflicts can occur between the control specified by the configuration. PCI Control Register. This register must be initialized by the DSP ROM code prior to PCI enumeration. (It has no effect in ISA or USB mode.) Once the Configuration Ready bit has been set to 1, the PCI Control Register becomes read-only, and further access by the DSP to configuration space is disallowed. The bits of this register are shown in Table 6. Target accesses to registers and DSP memory can go through any function. As long as the Memory Space access enable bit is set in that function, then PCI memory accesses whose addresses match the locations programmed into a function, BARs 1–3 will be able to read or write any visible register or memory location within the ADSP-2192M. Similarly, if I/O space access enable is set, then PCI I/O accesses can be performed via BAR4. PCI Configuration Space The ADSP-2192M PCI Interface provides three separate configuration spaces, one for each possible function. This document describes the registers in each function, their reset condition, and how the three functions interact to access and control the ADSP2192M hardware. REV. 0 Within the Power Management section of the configuration blocks, there are a few interactions. The part will stay in the highest power state between the three configurations. –9– ADSP-2192M Table 7. PCI Configuration Space 0, 1, and 2 Address Name Reset Comments 0x01–0x00 0x03–0x02 0x05–0x04 Vendor ID Config 0 Device ID Config 1 Device ID Config 2 Device ID Command Register 0x11D4 0x2192 0x219A 0x219E 0x0 0x07–0x06 Status Register 0x0 0x08 0x0B–0x09 0x0C 0x0D 0x0E 0x0F 0x13–0x10 Revision ID Class Code Cache Line Size Latency Timer Header Type BIST Base Address 1 0x0 0x48000 0x0 0x0 0x80 0x0 0x08 Writable from the DSP during initialization Writable from the DSP during initialization Writable from the DSP during initialization Writable from the DSP during initialization Bus Master, Memory Space Capable, I/O Space Capable Bits enabled: Capabilities List, Fast B2B, Medium Decode Writable from the DSP during initialization Writable from the DSP during initialization Read Only 0x17–0x14 0x1B–0x18 0x1F–0x1C 0x23–0x20 0x27–0x24 0x2B–0x28 Base Address2 Base Address3 Base Address4 Base Address5 Base Address6 Config 0 CardBus CIS Pointer Config 1 CardBus CIS Pointer Config 2 CardBus CIS Pointer Subsystem Vendor ID Config 0 Subsystem Device ID Config 1 Subsystem Device ID Config 2 Subsystem Device ID Expansion ROM Base Address Capabilities Pointer Interrupt Line Interrupt Pin Min_Gnt Max_Lat Capability ID Next_Cap_Ptr Power Management Capabilities Power Management Control/Status Power Management Bridge Power Management Data 0x08 0x08 0x01 0x0 0x0 0x1FF03 0x1FE03 0x1FD03 0x11D4 0x2192 0x219A 0x219E 0x0 0x40 0x0 0x1 0x1 0x4 0x1 0x0 0x6C22 0x0 0x0 0x0 0x2D–0x2C 0x2F–0x2E 0x33–0x30 0x34 0x3C 0x3D 0x3E 0x3F 0x40 0x41 0x43–0x42 0x45–0x44 0x46 0x47 PCI Memory Map The ADSP-2192M On-Chip Memory is mapped to the PCI Address Space. Because some ADSP-2192M Memory Blocks are 24 bits wide (Program Memory) while others are 16 bits (Data Memory), two different footprints are available in PCI Address Space. These footprints are available to each PCI function by accessing different PCI Base Address Registers (BAR). BAR2 supports 24-bit “Unpacked” Memory Access. BAR3 supports 16-bit “Packed” Memory Access. In 24-bit (BAR2) Mode, each 32 bits (four Consecutive PCI Byte Address Locations, which make up one PCI Data word) correspond to a single ADSP-2192M Memory Location. BAR2 Multifunction bit set Unimplemented Register Access for all ADSP-2192M Registers, Prefetchable Memory 24-bit DSP Memory Access 16-bit DSP Memory Access I/O access for control registers and DSP memory Unimplemented Unimplemented CIS RAM Pointer - Function 0 (Read Only) CIS RAM Pointer - Function 1 (Read Only) CIS RAM Pointer - Function 2 (Read Only) Writable from the DSP during initialization Writable from the DSP during initialization Writable from the DSP during initialization Writable from the DSP during initialization Unimplemented Read Only Uses INTA Pin Read Only Read Only Power Management Capability Identifier Read Only Writable from the DSP during initialization Bits 15 and 8 initialized only on Power-up Unimplemented Unimplemented Mode is typically used for Program Memory Access. Byte3 is always unused. Bytes[2:0] are used for 24-bit Memory Locations. As shown in Figure 3, Bytes[2:1] are used for 16-bit Memory Locations. In 16-bit (BAR3) Mode (Figure 4), each 32-bit (four Consecutive PCI Byte Address Locations) PCI Data Word corresponds to two ADSP-2192M Memory Locations. Bytes[3:2] contain one 16-bit Data Word, Bytes[1:0] contain a second 16-bit Data Word. BAR3 Mode is typically used for Data Memory Access. Only the 16 MSBs of a Data Word are accessed in 24-bit Blocks; the 8 LSBs are ignored. –10– REV. 0 ADSP-2192M PCI DWORD BYTE3 BYTE3 IS ALWAYS UNUSED BYTE2 BYTE1 BYTE0 PCI BYTE ADDRESS DSP WORD ADDRESS BYTE0 IS UNUSED BY 16-BIT MEMORY LOCATIONS 0x0 0000 ALLOWED BYTE ENABLES: CBE = 1100 CBE = 0011 0x0 FFFC 0x1 0000 0x0000 16K 24-BIT BLOCK 0x3FFF 0x4000 UNUSED 16K 16-BIT BLOCK UNUSED 0x1 FFFC 0x7FFF Figure 3. PCI Addressing for 24-Bit and 16-Bit Memory Blocks in 24-Bit Access (BAR2) Mode PCI DWORD BYTE3 PCI BYTE ADDRESS BYTE2 BYTE1 DATA WORD N + 1 BYTE0 DATA WORD N 0x0 0000 0x0000 DATA WORD N ALL BYTES ARE USED. ALLOWED BYTE ENABLES: CBE = 1100 CBE = 0011 CBE = 0000 0x0 7FFE 0x0 8000 DATA WORD N + 1 16K 24-BIT BLOCK 16K 16-BIT BLOCK DSP WORD ADDRESS UNUSED 0x3FFF 0x4000 UNUSED 0x7FFF 0x0 FFFE Figure 4. PCI Addressing for 24-Bit and 16-Bit Memory Blocks in 16-Bit Access (BAR3) Mode 24-Bit PCI DSP Memory Map (BAR2) The complete PCI address footprint for the ADSP-2192M DSP Memory Spaces in 24-bit (BAR2) Mode is shown in Table 8. Table 8. 24-Bit PCI DSP Memory Map (BAR2 Mode)1 Block Byte3 Byte2 Byte1 Byte0 Offset DSP P0 Data RAM Block 0 UNUSED UNUSED ... UNUSED D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] UNUSED UNUSED ... UNUSED 0x0000 0000 0x0000 0004 ... 0x0000 FFFC DSP P0 Data RAM Block 1 UNUSED UNUSED ... UNUSED D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] UNUSED UNUSED ... UNUSED 0x0001 0000 0x0001 0004 ... 0x0001 FFFC DSP P0 Data RAM Block 2 UNUSED UNUSED ... UNUSED D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] UNUSED UNUSED ... UNUSED 0x0002 0000 0x0002 0004 ... 0x0002 FFFC DSP P0 Data RAM Block 3 UNUSED UNUSED ... UNUSED D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] UNUSED UNUSED ... UNUSED 0x0003 0000 0x0003 0004 ... 0x0003 FFFC DSP P0 Program RAM Block UNUSED UNUSED ... UNUSED D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] 0x0004 0000 0x0004 0004 ... 0x0004 FFFC REV. 0 –11– ADSP-2192M Table 8. 24-Bit PCI DSP Memory Map (BAR2 Mode)1 (continued) Block Byte3 Byte2 Byte1 Byte0 Offset DSP P0 Program ROM Block UNUSED UNUSED ... UNUSED D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] 0x0005 0000 0x0005 0004 ... 0x0005 3FFC Reserved Space RESERVED ... RESERVED RESERVED ... RESERVED RESERVED ... RESERVED RESERVED ... RESERVED 0x0005 4000 ... 0x0007 FFFC DSP P1 Data RAM Block 0 UNUSED UNUSED ... UNUSED D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] UNUSED UNUSED ... UNUSED 0x0008 0000 0x0008 0004 ... 0x0008 FFFC DSP P1 Data RAM Block 1 UNUSED UNUSED ... UNUSED D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] Reserved Space UNUSED UNUSED ... UNUSED D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] UNUSED UNUSED ... UNUSED UNUSED UNUSED ... UNUSED 0x0009 0000 0x0009 0004 ... 0x0009 FFFC 0x000A 0000 0x000A 0004 ... 0x000B FFFC DSP P1 Program RAM Block UNUSED UNUSED ... UNUSED D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] 0x000C 0000 0x000C 0004 ... 0x000C FFFC DSP P1 Program ROM Block UNUSED UNUSED ... UNUSED D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] 0x000D 0000 0x000D 0004 ... 0x000D 3FFC Reserved Space RESERVED ... RESERVED RESERVED ... RESERVED RESERVED ... RESERVED RESERVED ... RESERVED 0x000D 4000 ... 0x000F FFFC 1 The “. . .” entries in this table indicate the continuation of the pattern shown in the first rows of each section. 16-Bit PCI DSP Memory Map (BAR3) The complete PCI address footprint for the ADSP-2192M DSP Memory Spaces in 16-bit (BAR3) Mode is shown in Table 9. Table 9. 16-Bit PCI DSP Memory Map (BAR3 Mode)1 Block Byte3 Byte2 Byte1 Byte0 Offset DSP P0 Data RAM Block 0 D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] 0x0000 0000 0x0000 0004 ... 0x0000 7FFC DSP P0 Data RAM Block 1 D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] 0x0000 8000 0x0000 8004 ... 0x0000 FFFC DSP P0 Data RAM Block 2 D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] 0x0001 0000 0x0001 0004 ... 0x0001 7FFC –12– REV. 0 ADSP-2192M Table 9. 16-Bit PCI DSP Memory Map (BAR3 Mode)1 (continued) Block Byte3 Byte2 Byte1 Byte0 Offset DSP P0 Data RAM Block 3 D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] 0x0001 8000 0x0001 8004 ... 0x0001 FFFC DSP P0 Program RAM Block D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] 0x0002 0000 0x0002 0004 ... 0x0002 7FFC DSP P0 Program ROM Block D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] 0x0002 8000 0x0002 8004 ... 0x0002 9FFC Reserved Space RESERVED ... RESERVED RESERVED ... RESERVED RESERVED ... RESERVED RESERVED ... RESERVED 0x0002 A000 ... 0x0003 FFFC DSP P1 Data RAM Block 0 D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] 0x0004 0000 0x0004 0004 ... 0x0004 7FFC DSP P1 Data RAM Block 1 D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] D[15:8] D[15:8] ... D[15:8] D[7:0] D[7:0] ... D[7:0] 0x0004 8000 0x0004 8004 ... 0x0004 FFFC Reserved Space RESERVED ... RESERVED RESERVED ... RESERVED RESERVED ... RESERVED RESERVED ... RESERVED 0x0005 0000 ... 0x0005 FFFC DSP P1 Program RAM Block D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] 0x0006 0000 0x0006 0004 ... 0x0006 7FFC DSP P1 Program ROM Block D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] D[23:16] D[23:16] ... D[23:16] D[15:8] D[15:8] ... D[15:8] 0x0006 8000 0x0006 8004 ... 0x0006 9FFC Reserved Space RESERVED ... RESERVED RESERVED ... RESERVED RESERVED ... RESERVED RESERVED ... RESERVED 0x0006 A000 ... 0x0007 FFFC 1 The “. . .” entries in this table indicate the continuation of the pattern shown in the first rows of each section. 16-Bit PCI DSP I/O Memory Map (BAR4) Using the USB Interface PCI Base Address Register (BAR4) allows indirect access to the ADSP-2192M Control Registers and DSP Memory. The DSP Memory Indirect Access Registers accessible from BAR4 are shown in Table 10. The ADSP-2192M USB design enables the ADSP-2192M to be configured and attached to a single device with multiple interfaces and various endpoint configurations, as follows: DSP P0 Memory Indirect Address Space occupies PCI BAR4 Space 0x000000 through 0x01FFFF DSP P1 Memory Indirect Address Space occupies PCI BAR4 Space 0x020000 through 0x03FFFF All Indirect DSP Memory Accesses are 24-bit or 16-bit Word Accesses. REV. 0 1. Programmable descriptors and a class-specific command interpreter are accessible through the USB 8052 registers. An 8052 compatible MCU is supported on-board, to enable soft downloading of different configurations, and support of standard or class-specific commands. 2. A total of eight user-defined endpoints are provided. Endpoints can be configured as BULK, ISO, or INT, and can be grouped. –13– ADSP-2192M Table 10. 16-Bit PCI DSP I/O Space Indirect Access Registers Map (BAR4 Mode) Table 11. USB DSP Register Definitions (continued) Page Address Offset Name 0x03–0x00 Control Register Address 0x07–0x04 Control Register Data 0x0B–0x08 DSP Memory Address 0x0F–0x0C DSP Memory Data Reset Comments 0x0000 Address and direction control for register accesses Data for register accesses 0x0000 0x0C 0x46–0x47 DSP Memory Buffer RD Offset 0x0C 0x48–0x49 DSP Memory Buffer WR Offset 0x0C 0x50–0x53 DSP Memory Buffer Base Addr 0x0C 0x54–0x55 DSP Memory Buffer Size 0x0C 0x56–0x57 DSP Memory Buffer RD Offset 0x0C 0x58–0x59 DSP Memory Buffer WR Offset 0x0C 0x60–0x63 DSP Memory Buffer Base Addr 0x0C 0x64–0x65 DSP Memory Buffer Size 0x0C 0x66–0x67 DSP Memory Buffer RD Offset 0x0C 0x68–0x69 DSP Memory Buffer WR Offset 0x0C 0x70–0x73 DSP Memory Buffer Base Addr 0x0C 0x74–0x75 DSP Memory Buffer Size 0x0C 0x76–0x77 DSP Memory Buffer RD Offset 0x0C 0x78–0x79 DSP Memory Buffer WR Offset 0x0C 0x80–0x81 USB Descriptor Vendor ID 0x0C 0x84–0x85 USB Descriptor Product ID 0x0C 0x86–0x87 USB Descriptor Release Number 0x0C 0x88–0x89 USB Descriptor Device Attributes 0x000000 Address and Direction control for Indirect DSP memory accesses 0x000000 Data for DSP memory accesses USB DSP Register Definitions For each endpoint, four registers are defined to provide a memory buffer in the DSP. These registers are defined for each endpoint shared by all defined interfaces, for a total of 4 8 = 32 registers. These registers are read/write by the DSP only. They are described in Table 11. Table 11. USB DSP Register Definitions Page Address Name Comment 0x0C 0x0–0x3 DSP Memory Buffer Base Addr DSP Memory Buffer Size DSP Memory Buffer RD Offset DSP Memory Buffer WR Offset DSP Memory Buffer Base Addr DSP Memory Buffer Size DSP Memory Buffer RD Offset DSP Memory Buffer WR Offset DSP Memory Buffer Base Addr DSP Memory Buffer Size DSP Memory Buffer RD Offset DSP Memory Buffer WR Offset DSP Memory Buffer Base Addr DSP Memory Buffer Size DSP Memory Buffer RD Offset DSP Memory Buffer WR Offset DSP Memory Buffer Base Addr DSP Memory Buffer Size EP4 0x0C 0x4–0x5 0x0C 0x6–0x7 0x0C 0x8–0x9 0x0C 0x10–0x13 0x0C 0x14–0x15 0x0C 0x16–0x17 0x0C 0x18–0x19 0x0C 0x20–0x23 0x0C 0x24–0x25 0x0C 0x26–0x27 0x0C 0x28–0x29 0x0C 0x30–0x33 0x0C 0x34–0x35 0x0C 0x36–0x37 0x0C 0x38–0x39 0x0C 0x40–0x43 0x0C 0x44–0x45 Name EP4 EP4 EP4 EP5 Comment EP8 EP8 EP9 EP9 EP9 EP9 EP10 EP10 EP10 EP10 EP11 EP11 EP11 EP11 EP5 EP5 USB DSP Memory Buffer Base Addr Register EP5 Points to the base address for the DSP memory buffer assigned to this endpoint. EP6 BA[17:0] = Memory Buffer Base Address EP6 EP6 EP6 USB DSP Memory Buffer Size Register Indicates the size of the DSP memory buffer assigned to this endpoint. SZ[15:0] = Memory Buffer Size USB DSP Memory Buffer RD Pointer Offset Register EP7 EP7 EP7 The offset from the base address for the read pointer of the memory buffer assigned to this endpoint. RD[15:0] = Memory Buffer RD Offset USB DSP Memory Buffer WR Pointer Offset Register EP7 EP8 The offset from the base address for the write pointer of the memory buffer assigned to this endpoint. WR[15:0] = Memory Buffer WR Offset EP8 –14– REV. 0 ADSP-2192M USB Descriptor Vendor ID USB Descriptor Device Attributes The Vendor ID returned in the GET DEVICE DESCRIPTOR command is contained in this register. The DSP can change the Vendor ID by writing to this register during the Serial EEPROM initialization. The default Vendor ID is 0x0456, which corresponds to Analog Devices, Inc. The device-specific attributes returned in the GET DEVICE DESCRIPTOR command are contained in this register. The DSP can change the attributes by writing to this register during the Serial EEPROM initialization. The default attributes are 0x80FA, which correspond to bus-powered, no remote wake-up, and max power = 500 mA. V[15:0] = Vendor ID (default = 0x0456) • SP: 1 = self-powered, 0 = bus-powered (default = 0) USB Descriptor Product ID • RW: 1 = have remote wake-up capability, 0 = no remote wake-up capability (default = 0) The Product ID returned in the GET DEVICE DESCRIPTOR command is contained in this register. The DSP can change the Product ID by writing to this register during the Serial EEPROM initialization. The default Product ID is 0x2192. • C[7:0] = power consumption from bus, expressed in 2 mA units (default = xFA 500 mA) P[15:0] = Product ID (default = 0x2192) USB DSP MCU Register Definitions USB Descriptor Release Number MCU registers, described in Table 12, are defined in four memory spaces that are grouped by the following address ranges: The Release Number returned in the GET DEVICE DESCRIPTOR command is contained in this register. The DSP can change the Release Number by writing to this register during the Serial EEPROM initialization. The default Release Number is 0x0100, which corresponds to Version 01.00. R[15:0] = Release Number (default = 0x0100) • 0x0XXX—This address range defines general-purpose USB status and control registers • 0x1XXX—This address range defines registers that are specific to endpoint setup and control • 0x2XXX—This address range defines the registers used for REGIO accesses to the DSP register space • 0x3XXX—This address range defines the MCU program memory write address space Table 12. USB MCU Register Definitions Address Name Comments 0x0000–0x0007 0x0008–0x000F 0x0010–0x0011 0x0012–0x0013 0x0014–0x0015 0x0016–0x0017 0x0030–0x0031 0x0032–0x0033 0x0034–0x0035 0x1000–0x1001 0x1002–0x1003 0x1004–0x1005 0x1006–0x1007 0x1008–0x1009 0x100A–0x100B 0x100C–0x100D 0x100E–0x100F 0x1010–0x1011 0x1012–0x1013 0x1014–0x1015 0x1016–0x1017 0x1018–0x1019 0x101A–0x101B 0x101C–0x101D 0x101E–0x101F 0x1020–0x1021 0x1040–0x1043 USB SETUP Token Cmd USB SETUP Token Data USB SETUP Counter USB Control USB Address/Endpoint USB Frame Number USB Serial EEPROM Mailbox 1 USB Serial EEPROM Mailbox 2 USB Serial EEPROM Mailbox 3 USB EP4 Description USB EP4 NAK USB EP5 Description USB EP5 NAK USB EP6 Description USB EP6 NAK USB EP7 Description USB EP7 NAK USB EP8 Description USB EP8 NAK USB EP8 Description USB EP9 NAK USB EP10 Description USB EP10 NAK USB EP11 Description USB EP11 NAK USB EP STALL USB EP1 Code Download Base Address Eight Bytes Total Eight Bytes Total 16-bit Counter Miscellaneous control including re-attach Address of device/active endpoint Current frame number Defined by Analog Devices Defined by Analog Devices Defined by Analog Devices Configures endpoint Counter Configures endpoint Counter Configures endpoint Counter Configures endpoint Counter Configures endpoint Counter Configures endpoint Counter Configures endpoint Counter Configures endpoint Counter Policy Starting address for code download on endpoint 1 REV. 0 –15– ADSP-2192M Table 12. USB MCU Register Definitions (continued) Address Name 0x1044–0x1047 0x1048–0x104B 0x1060–0x1063 USB EP2 Code Download Base Address Starting address for code download on endpoint 2 USB EP3 Code Download Base Address Starting address for code download on endpoint 3 USB EP1 Code Current Write Pointer Offset Current write pointer offset for code download on endpoint 1 USB EP2 Code Current Write Pointer Offset Current write pointer offset for code download on endpoint 2 USB EP3 Code Current Write Pointer Offset Current write pointer offset for code download on endpoint 3 USB Register I/O Address USB Register I/O Data USB MCU Program Memory 0x1064–0x1067 0x1068–0x106B 0x2000–0x2001 0x2002–0x2003 0x3000–0x3FFF Comments USB Endpoint Description Register USB Endpoint 2 Code Download Base Address Register The endpoint description register provides the USB core with information about the endpoint type, direction, and max packet size. This register is read/write by the MCU only. This register is defined for endpoints 4–11. This register contains an 18-bit address which corresponds to the starting location for DSP code download on endpoint 2. This register is read/write by the MCU only. USB Endpoint 3 Code Download Base Address Register • PS[9:0] MAX Packet Size for endpoint This register contains an 18-bit address which corresponds to the starting location for DSP code download on endpoint 3. This register is read/write by the MCU only. • LT[1:0] Last transaction indicator bits: 00 = Clear, 01 = ACK, 10 = NAK, or 11 = ERR • TY[1:0] Endpoint type bits: 00 = DISABLED, 01 = ISO, 10 = Bulk, or 11 = Interrupt USB Endpoint 1 Code Current Write Pointer Offset Register • DR Endpoint direction bit: 1 = IN or 0 = OUT This register contains an 18-bit address which corresponds to the current write pointer offset from the base address register for DSP code download on endpoint 1. The sum of this register and the EP1 Code Download Base Address Register represents the last DSP PM location written. • TB Toggle bit for endpoint. Reflects the current state of the DATA toggle bit. USB Endpoint NAK Counter Register This register records the number of sequential NAKs that have occurred on a given endpoint. This register is defined for endpoints 4–11. This register is read/write by the MCU only. This register is read by the MCU only and is cleared to 3FFFF (–1) when the Endpoint 1 Code Download Base Address Register is updated. • N[3:0] NAK counter. Number of sequential NAKs that have occurred on a given endpoint. When N[3:0] is equal to the base NAK counter NK[3:0], a zero-length packet or packet less that maxpacketsize will be issued. USB Endpoint 2 Code Current Write Pointer Offset Register This register contains an 18-bit address that corresponds to the current write pointer offset from the base address register for DSP code download on endpoint 2. The sum of this register and the EP2 Code Download Base Address Register represents the last DSP PM location written. • ST 1 = Endpoint is stalled USB Endpoint Stall Policy Register This register contains NAK count and endpoint FIFO error policy bit. The STALL status bits for endpoints 1–3 are included as well. This register is read/write by the MCU only. This register is read by the MCU only and is cleared to 3FFFF (–1) when the Endpoint 2 Code Download Base Address Register is updated. • ST[3:1] 1 = Endpoint is stalled. ST[1] maps to endpoint 1, ST[2] maps to endpoint 2, etc. USB Endpoint 3 Code Current Write Pointer Offset Register • NK[3:0] Base NAK counter. Determines how many sequential NAKs are issued before sending zero length packet on any given endpoint. • FE FIFO error policy. 1 = When endpoint FIFO is overrun/underrun, STALL endpoint USB Endpoint 1 Code Download Base Address Register This register contains an 18-bit address which corresponds to the starting location for DSP code download on endpoint 1. This register is read/write by the MCU only. This register contains an 18-bit address which corresponds to the current write pointer offset from the base address register for DSP code download on endpoint 3. The sum of this register and the EP3 Code Download Base Address Register represents the last DSP PM location written. This register is read by the MCU only and is cleared to 3FFFF (–1) when the Endpoint 3 Code Download Base Address Register is updated. –16– REV. 0 ADSP-2192M USB SETUP Token Command Register USB Control Register This register is defined as eight bytes long and contains the data sent on the USB from the most recent SETUP transaction. This register is read by the MCU only. This register controls various USB functions. This register is read/write by the MCU only. • MO 1 = MCU has completed boot sequence and is ready to respond to USB commands USB SETUP Token Data Register If the most recent SETUP transaction involves a data OUT stage, this register is defined as eight bytes long and contains the data sent on the USB during the data stage. This is also where the MCU will write data to be sent in response to a SETUP transaction involving a data IN stage. This register is read/write by the MCU only. • DI 1 = Disconnect CONFIG device and enumerate again using the downloaded MCU configuration USB SETUP Counter Register • IIN = Current interrupt is for an IN token This register provides information as the total size of the setup transaction data stage. This register is read/write by the MCU only. • C[3:0] Total amount of data (bytes) to be sent/received during the data stage of the SETUP transaction USB Register I/O Address Register This register contains the address of the ADSP-2192M register that is to be read/written. This register is read/write by the MCU only. • A[15] Start ADSP-2192M read/write cycle • A[14] 1 = WRITE, 0 = READ • BB 1 = After reset boot from MCU RAM; 0 = after reset boot from MCU ROM • INT = Active interrupt for the 8052 MCU • ISE = Current interrupt is for a SETUP token • IOU = Current interrupt is for an OUT token • ER = Error in the current SETUP transaction. Generate STALL condition on EP0. USB Address/Endpoint Register This register contains the USB address and active endpoint. This register is read/write by the MCU only. • A[6:0] USB address assigned to device • EP[3:0] USB last active endpoint USB Frame Number Register • A[13:0] ADSP-2192M address to read/write This register contains the last USB frame number. This register is read by the MCU only. USB Register I/O Data Register • FN[10:0] USB frame number This register contains the data of the ADSP-2192M register which has been read or is to be written. This register is read/write by the MCU only. • D[15:0] During READ this register contains the data read from the ADSP-2192M; during WRITE this register is the data to be written to the ADSP-2192M. General USB Device Definitions The following tables define the USB device descriptors: Table 13 describes the USB device descriptor; offset fields 8–13 are userdefinable via Serial EEPROM. Table 14 describes the USB configuration descriptor; offset fields 7–8 are user-definable via Serial EEPROM. Table 15, Table 16, and Table 17 describe the USB string descriptor indexes. Table 13. CONFIG DEVICE Device Descriptor Offset Field Description Value 0 1 2–3 4 5 6 7 8–9 10–11 12–13 14 15 16 17 bLength bDescriptorType bcdUSB bDeviceClass bDeviceSubClass bDeviceProtocol bMaxPacketSize idVendor (L) idProduct (L) bcdDevice (L) iManufacturer iProduct iSerialNumber bNumConfigurations Length = 18 bytes Type = DEVICE USB Spec 1.1 Device class vendor specific Device sub-class vendor specific Device protocol vendor specific Max packet size for EP0 = eight bytes Vendor ID (L) = 0456 ADI Product ID (L) = ADSP-2192M Device release number = 1.00 Manufacturer index string Product index string Serial number index string Number of configurations = 1 0x12 0x01 0x0110 0xFF 0xFF 0xFF 0x08 0x0456 0x2192 0x0100 0x01 0x02 0x00 0x01 REV. 0 –17– ADSP-2192M Table 14. CONFIG DEVICE Configuration Descriptor Offset Field Description Value 0 1 2 3 4 5 6 7 8 bLength bDescriptorType wTotalLength (L) wTotalLength (H) bNumInterfaces bConfigurationValue iConfiguration bmAttributes MaxPower Descriptor Length = nine bytes Descriptor Type = Configuration Total Length (L) Total Length (H) Number of Interfaces Configuration Value Index of string descriptor (None) Bus powered, no wake-up Max power = 500 mA 0x09 0x02 0x12 0x00 0x01 0x01 0x00 0x80 0xFA Table 15. CONFIG DEVICE String Descriptor Index 0 Offset Field Description Value 0 1 2 bLength bDescriptorType wLANGID[0] Descriptor Length = 4 bytes Descriptor Type = String LangID = 0409 (US English) 0x04 0x03 0x0409 Table 16. CONFIG DEVICE Descriptor Index 1 (Manufacturer) Offset Field Description Value 0 1 2–19 bLength bDescriptorType bString Descriptor Length = 20 bytes Descriptor Type = String ADI 0x14 0x03 Table 17. CONFIG DEVICE String Descriptor Index 2 (Product) Offset Field Description Value 0 1 2–31 bLength bDescriptorType bString Descriptor Length = 34 bytes Descriptor Type = String Analog Devices USB Device 0x22 0x03 • FIXED ENDPOINTS Note: The GENERIC endpoints are shared between all interfaces. • CONTROL ENDPOINT 0 Endpoint 0 Definition Configuration 0, 1, and 2 Device Definition • Type: Control In addition to the normally defined USB standard device requests, the following vendor specific device requests are supported with the use of EP0. These requests are issued from the host driver via normal SETUP transactions on the USB. • Dir: Bidirectional • Maxpacketsize: 8 • BULK OUT ENDPOINT 1, 2, 3 = Used for code download to DSP USB MCU Code Download • Type: Bulk USB MCUCODE is a three-stage control transfer with an OUT data stage. Stage 1 is the SETUP stage, stage 2 is the data stage involving the OUT packet, and stage 3 is the status stage. The length of the data stage is determined by the driver and is specified by the total length of the MCU code to be downloaded. See Table 18 for details about the USB MCUCODE (code download) fields. • Dir: OUT • Maxpacketsize: 64 • PROGRAMMABLE ENDPOINTS: 4 5 6 7 8 9 10 11 • Programmable in: • Type: via USB Endpoint Description Register • Direction: via USB Endpoint Description Register USB REGIO (Write) • Maxpacket size: via USB Endpoint Description Register Address 15–15 = 1 indicates a write to the MCU register space; Address 15–15 = 0 indicates a write to the DSP register space. When accessing DSP register space, the MCU must write the data to be written into the USB Register I/O Data register and • Memory Allocation: via DSP Memory Buffer Base Addr, DSP Memory Buffer Size, DSP Memory Buffer RD Pointer Offset, DSP Memory Buffer Write Pointer Offset Registers –18– REV. 0 ADSP-2192M Table 18. USB MCUCODE (Code Download) Table 20. USB REGIO (Register Read) Offset Field Size Value Description Offset Field Size Value Description 0 bmRequest 1 0x40 0 bmRequest 1 0xC0 1 bRequest 1 0xA1 2 3 4 5 6 wValue (L) wValue (H) wIndex (L) wIndex (H) wLength (L) 1 1 1 1 1 XXX XXX 0x00 0x00 0xXX1 Vendor Request, OUT USB MCUCODE Address 7–0 Address 15–8 1 2 3 4 5 6 bRequest wValue (L) wValue (H) wIndex (L) wIndex (H) wLength (L) 1 1 1 1 1 1 0xA0 XXX XXX 0x00 0x00 0x02 Vendor Request, IN USB REGIO Address 7–0 Address 15–8 7 wLength (H) 1 0x00 7 wLength (H) 1 0xYY2 1 XX 2 YY Length = XX bytes Length = YY bytes DSP Code Download Because EP0 has a max packet size of only eight, downloading DSP code on EP0 can be inefficient when operating on a UHCI controller that allows only a fixed quantity of control transactions per frame. Therefore, to gain better throughput for code download, downloading of DSP code involves synchronizing a control SETUP command on EP0 with BULK OUT commands on endpoints 1, 2, or 3. Each endpoint has an associated DSP download address that is set by using USB REGIO (write) command. is user-specified. is user-specified. write the address to be written to the USB Register I/O Address register. Bit 15 of the USB Register I/O Address register starts the transaction and Bit 14 is set to one to indicate a WRITE. USB REGIO (register write) is a three-stage control transfer with an OUT data stage. Stage 1 is the SETUP stage, stage 2 is the data stage involving the OUT packet, and stage 3 is the status stage. See Table 19 for details about the USB REGIO (register write) fields. Because three possible interfaces are supported, each interface has its own DSP download address and uses its own BULK pipe to download code. The driver for each interface must set the download address before beginning to use the BULK pipe to download DSP code. The download address will auto-increment as each byte of data is sent on the BULK pipe to the DSP. Table 19. USB REGIO (Register Write) Offset Field Size Value Description 0 bmRequest 1 0x40 1 2 3 4 5 6 bRequest wValue (L) wValue (H) wIndex (L) wIndex (H) wLength (L) 1 1 1 1 1 1 0xA0 XXX XXX 0x00 0x00 0x02 Vendor Request, OUT USB REGIO Address 7–0 Address 15–8 7 wLength (H) 1 0x00 DSP instructions are three bytes long, and USB BULK pipes have even-number packet sizes. The instructions to be downloaded must be formatted into four-byte groups with the least significant byte always zero. The USB interface strips off the least significant byte and properly formats the DSP instruction before writing it into the program memory. For example, to write the three-byte opcode 0x400000 to DSP program memory, the driver sends 0x40000000 down the BULK pipe. Length = 02 bytes The following example illustrates the proper order of commands and synchronizing that the driver must follow. 1. Device enumerates with two interfaces. Each interface has the capability to download DSP code and can initiate at any time. USB REGIO (Read) Address 15–15 = 1 indicates a read to the MCU register space; Address 15–15 = 0 indicates a read to the DSP register space. When accessing DSP register space, the MCU must write the address to be read to the USB Register I/O Address register. Bit 15 of the USB Register I/O Address register starts the transaction, and Bit 14 is set to zero to indicate a READ. The data read will be placed into the USB Register I/O Data register. USB REGIO (register read) is a three-stage control transfer with an IN data stage. Stage 1 is the SETUP stage, stage 2 is the data stage involving the IN packet, and stage 3 is the status stage. See Table 20 for details about the USB REGIO (register read) fields. REV. 0 Length = 02 bytes 2. The driver for interface 1 begins code download by sending the USB REGIO (write) command with the starting download address. The driver must wait for this command to finish before starting code download. 3. The driver for interface 2 begins code download by sending the USB REGIO (write) command with the starting download address. The driver must wait for this command to finish before starting code download. 4. Each driver now streams the code to be downloaded to the DSP: driver 1 onto BULK EP1 for interface 1, and driver 2 onto BULK EP2 for interface 2. The code is written to the DSP in 3-byte instructions starting at the –19– ADSP-2192M location specified by the USB REGIO (write) command. The driver must wait for each command to finish before sending a new code download address. 5. If there is more code to be downloaded at a different starting address, the driver begins the entire sequence again, using steps 1–4. General Comments: • DSP code download is only available after the ADSP2192M has re-enumerated using the MCU soft firmware. The DSP code download command will not be available in the MCU boot ROM for the default CONFIG device. • After setting the download addresses using the USB REGIO (write) command, code download can be initiated for any length using normal BULK traffic. Example Initialization Process After attachment to the USB bus, the ADSP-2192M identifies itself as a CONFIG device with one endpoint, which refers to its one control, EP0. This will cause a generic user-defined CONFIG driver to load. The CONFIG driver downloads appropriate MCU code to setup the MCU, which includes the specific device descriptors, interfaces, and endpoints. The external Serial EEPROM is read by the DSP and transferred to the MCU. The CONFIG driver through the control EP0 pipe generates a register read to determine the configuration value. Based on this configuration code, the host downloads the proper USB configurations to the MCU. 7. ADSL driver downloads code to DSP for ADSL service. DSP also initializes the USB Endpoint Description Register, DSP Memory Buffer Base Addr Register, DSP Memory Buffer Size Register, DSP Memory Buffer RD Pointer Offset, and DSP Memory Buffer WR Pointer Offset registers for each endpoint. Endpoints can only be used when these registers have been written. ADSL service is now available. 8. FAX driver downloads code to DSP for FAX service. DSP also initializes the USB Endpoint Description Register, DSP Memory Buffer Base Addr Register, DSP Memory Buffer Size Register, DSP Memory Buffer RD Pointer Offset, and DSP Memory Buffer WR Pointer Offset registers for each endpoint. Endpoints can only be used when the above registers have been written. FAX service is now available. USB Data Pipe Operations All data transactions involving the generic endpoints (4–11) stream data into and out of the DSP memory via a dedicated USB hardware block. This hardware block manages all USB transactions for these endpoints and serves as a conduit for the data moving to and from the DSP memory FIFOs. There is no MCU involvement in the management of these data pipes. Table 21. Typical Configuration for ADSL Modem Finally, the driver writes the USB Control Register, causing the device to disconnect and then reconnect so the new downloaded configuration is enumerated by the system. Upon enumeration, each interface loads the appropriate device driver. An example of this procedure is configuring the ADSP-2192M to be an ADSL modem and a FAX modem. 2. The user-defined driver reads the device descriptor, which identifies the card as an ADSL/FAX modem. 4. Configuration specifies which endpoints are used (and their definitions). A typical configuration for ADSL appears in Table 21. 5. The user-defined driver downloads USB configuration for interface 2, which is the FAX modem. Configuration specifies which endpoints are used and their definitions. A typical configuration for FAX appears in Table 22. 6. The user-defined driver now writes the USB Config Register, which causes the device to disconnect and reconnect. The system enumerates all interfaces and loads the appropriate drivers. Type Max Packet Comment 1 4 5 6 BULK OUT BULK IN BULK OUT INT IN 64 64 64 16 DSP CODE ADSL RCV ADSL XMT STATUS Table 22. Typical Configuration for FAX Modem 1. ADSP-2192M device is attached to USB bus. System enumerates the CONFIG device in the ADSP-2192M first. A user-defined driver is loaded. 3. The user-defined driver downloads USB configuration and MCU code to the MCU for interface 1, which is the ADSL modem. End Point End Point Type Max Packet Comment 2 7 8 9 BULK OUT BULK IN BULK OUT INT IN 64 64 64 16 DSP CODE FAX RCV FAX XMT STATUS The USB data FIFOs for these generic endpoints exist in DSP memory space. The following memory buffer registers exist for each endpoint: • Base Address (18 bits) • Size (16 bits) – Offset from the Base Address • Read Offset (16 bits) – Offset from the Base Address • Write Offset (16 bits) – Offset from the Base Address As part of initialization, the DSP code sets up these FIFOs before USB data transactions for these endpoints can begin. When setting up these USB FIFOs, Base+Size/Read Offset/Write Offset cannot be greater than 18 bits. DSP memory addresses cannot exceed 18 bits (0x000000–0x03FFFF). –20– REV. 0 ADSP-2192M IN Transactions (Device to Host) The DSP memory interface on the ADSP-2192M only allows reads/writes of 16-bit words. It cannot handle byte transactions. Therefore, a 64-byte maxpacketsize means 32 DSP words. A single byte cannot be transferred to/from the DSP. Endpoint 0 does not have this limitation. Because these FIFOs exist in DSP memory, the DSP shares some pointer management tasks with the USB core. For OUT transactions, the write pointer is controlled by the USB core, while the read pointer is governed by the DSP. The opposite is true for IN transactions. When an IN transaction arrives for a particular endpoint, the USB core once again computes how much read data is available in the FIFO. It also determines if the amount of read data is greater than or equal to the maxpacketsize. If both conditions are met, the USB core will transfer the data. Upon receiving ACK from the host, the USB core updates the Memory Buffer Read Offset register. If the amount of read data is less than the maxpacketsize (a short packet), the USB core determines whether to send the data based upon a NAK count limit. This is a 4-bit field in the Endpoint Stall Policy register that can be programmed with a value indicating how many NAKs should be sent prior to transmitting a short packet. This allows flexibility in determining how IRPs are retired via short packets. Both the write and read pointers for each memory buffer would begin at zero. All USB buffers operate in a circular fashion. Once a pointer reaches the end of the buffer, it will need to be set back to zero. OUT Transactions (Host to Device) When an OUT transaction arrives for a particular endpoint, the USB core calculates the difference between the write and read pointers to determine the amount of room available in the FIFOs. If all of the OUT data arrives and the write pointer never catches up to the read pointer, that data is Backed and the USB core updates the Memory Buffer Write Offset register. Because the DSP controls the write pointer, it must determine if there is sufficient room in the FIFO for placing new data. Once it has completed writes to the FIFO, it needs to update the Memory Buffer Write Offset register. Sub-ISA Interface If at any time during the transaction the two pointers collide, the USB block responds with a NAK indicating that the host must resend the same data packet; in that case, the write pointer remains unchanged. In systems that combine the ADSP-2192M chip with other devices on a single PCI interface, the ADSP-2192M Sub-ISA mode is used to provide a simpler interface (to a PCI function ASIC), which bypasses the ADSP-2192M’s PCI interface. If for some reason the host sends more data than the maxpacketsize, the USB core accepts it, as long as there is sufficient room in the FIFO. In this mode, the Combo Master assumes all responsibility for interfacing the function to the PCI bus, including provision of Configuration Space registers for the ADSP-2192M system as a separate PnP function. In Sub-ISA Mode the PCI Pins are reconfigured for ISA operation as shown in Table 23. Because the DSP controls the read pointer, it must perform a similar calculation to determine if there is sufficient data in the FIFO to begin processing. Once The DSP has consumed some amount of data, it will need to update the Memory Buffer Read Offset register. Table 23. Sub-ISA (PCI) Pin Descriptions Pin Name PCI Direction1 ISA Alias ISA Direction ISA Description AD[15:0] AD[18:16] AD[31:22] RST CBE0 CBE1 CBE2 INTA AD21 AD20 AD19 PME CLK CLKRUN CLKRUN In/Out In/Out In/Out In In/Out In/Out In/Out Out (o/d) In/Out In/Out In/Out Out (o/d) In In/Out Out ISAD[15:0] ISAA[3:1] Unused RST IOW IOR AEN IRQ PDW1 PDW0 PME_EN PMERQ Unused IOCHRDY IOCHRDY In/Out In In In In In In Out In In In Out (o/d) In Out Out Data Register Address Tie to GND in Sub-ISA Mode Reset Write Strobe Read Strobe Chip Select (Access Enable) (CMOS) Interrupt (Active High) PCI D-state MSB (inverted) Power-Down PCI D-state LSB (inverted) Power-Down PME Enable Power Management Event Tie to GND in Sub-ISA Mode I/O Ready Acknowledge 1 o/d = Open Drain REV. 0 –21– ADSP-2192M Assertion of PDW1 low signals a power-down interrupt to the DSP. Deassertion of PDW1 high causes a wake-up of the DSP. The PME_EN output from the Combo Master should reflect the current PCI function PME_EN bit and should be connected to the ADSP-2192M AD20 pin. The PMI_EN bit should be set to enable interrupt and wake-up of the DSP upon any change of the PME_EN state. If PME_EN is turned off, the DSPs can wake up if necessary and then power themselves and the ADSP-2192M completely down (clocks stopped). In Sub-ISA mode, the ADSP-2192M’s PCI protocol is replaced with an ISA-like, asynchronous protocol controlled by the strobes IOR, IOW, and AEN. Access is possible only to the PCI Base Address 4 (BAR4) Registers (the InDirect Access Registers). The Sub-ISA Address Map is shown in Table 24. An active low RST input (to be derived from PCI RST and possible other sources) and an active-high IRQ interrupt output are available. Power Management is handled by the ADSP2192M inputs PDW1–0/PME_EN and the ADSP-2192M output PMERQ. PDW1–0 should be the inversion of the PCI power state in the function’s PMCSR register. PDW1 is connected to AD21, and PDW0 is connected to AD20. Table 24. Sub-ISA Indirect Access Registers ISAA[3:1] Name Reset Comments 0x0 0x1 0x2 0x3 0x5–0x4 Control Register Address Reserved Control Register Data Reserved DSP Memory Address 0x0000 Address and direction control for register accesses 0x0000 Data for register accesses 0x000000 0x7–0x6 DSP Memory Data 0x000000 Address and direction control for DSP memory accesses Data for DSP memory accesses. PCI Interface to DSP Memory Data FIFO Architecture The PCI interface can directly access the DSP memory space using DMA transfers. The transactions can be either slave transfers, in which the host initiates the transaction, or master transfers, in which the ADSP-2192M initiates the PCI transaction. The registers that control PCI DMA transfers are accessible from both the DSP (on the Peripheral Device Control Bus) and the PCI Bus. Each DSP core within the ADSP-2192M contains four FIFOs which provide a data communication path to the rest of the chip. Two of the FIFOs are input FIFOs, receiving data into the DSP. The other two FIFOs are transmit FIFOs, sending data from the DSP to the codec, AC’97 interface, or the other DSP. Each FIFO is eight words deep and sixteen bits wide. Interrupts to the DSP can be generated when some words have been received in the input FIFOs, or when some words are empty in the Transmit FIFOs. The PCI/Sub-ISA Bus uses the Peripheral Device Control Register Space which is distributed throughout the ADSP2192M and connected through the Peripheral Device Control Bus. The PCI bus can access these registers directly. USB Interface to DSP Memory The USB interface can directly access the DSP memory space using DMA transfers to memory locations specified by the USB endpoints. The registers that control USB endpoint DMA transfers are accessible from both the DSP (on the Peripheral Device Control Bus) and the USB Bus. The Peripheral Device Control Register Space is distributed throughout the ADSP-2192M and connected through the Peripheral Device Control Bus. The USB Bus can access these registers directly. AC’97 Codec Interface to DSP Memory Transfers from AC’97 data to DSP memory are accomplished using DMA transfer through the DSP FIFOs. Each DSP has four FIFOs available for data transfers to/from the AC’97 Codec Interface. The registers that control FIFO DMA transfers are only accessible from within the DSP and are defined as part of the core register space. The interface to the FIFOs on the DSP is simply a register interface to the Peripheral Interface bus. TX0, RX0, TX1, and RX1 are the primary FIFO registers in the DSP’s universal register map. The FIFOs can be used to generate interrupts to the DSP, based upon FIFO transactions, or they can initiate DMA requests. When communicating with the AC’97 interface, the Connection Enable bits in the control register are set to 10. Bit 3 selects stereo or mono transfers to and from the AC’97 interface. Bits 7–4 select the AC’97 slot associated with this FIFO. When stereo is selected, the slot identified and the next slot are both associated with the FIFO. Typically, stereo is selected for left and right data, and both left and right must be associated with the same external AC’97 codec and have their sample rates locked together. In this case, left and right data will alternate in the FIFO with the left data coming first. If the FIFO is enabled for the AC’97 interface, and a valid request for data comes along that the FIFO cannot fulfill, the transmitter underflow bit is set, indicating that an invalid value was sent over the selected slot. Similarly, on the receive side, if the FIFO is full and another valid word is received, the Overflow bit is sent to indicate the loss of data. –22– REV. 0 ADSP-2192M • RFF (Bit 13): Receive FIFO Full – Read Only. (0 = FIFO Not Full or 1 = FIFO Full) FIFO Control Registers The Transmit FIFO Control Register has the following bit field definitions: • RFE (Bit 14): Receive FIFO Empty – Read Only. (0 = FIFO Not Empty or 1 = FIFO Empty) • CE (Bits 1–0): Connection Enable (00 = Disable, 01 = Reserved, 10 = Connect to AC’97, and 11 = Reserved) • RO (Bit 15): Receive Overflow – Sticky, Write 1 Clear. (0 = FIFO Overflow has not occurred or 1 = FIFO Overflow has occurred) • DPSel (Bit 2): Reserved (0) • SMSel (Bit 3): Stereo/Mono Select - AC’97 Mode Only (0 = Mono Stream or 1 = Stereo Stream) Table 26. AC’97 Slot Select Values • SLOT (Bits 7–4): AC’97 Slot Select - AC’97 Mode Only Slot Mono Stereo • FIP (Bits 10–8): FIFO interrupt position. An interrupt is generated when FIP[2:0] words remain in the FIFO. The interrupt is level-sensitive. 0000–0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101–1111 Reserved Slot 3 Slot 4 Slot 5 Slot 6 Slot 7 Slot 8 Slot 9 Slot 10 Slot 11 Slot 12 Reserved Reserved Slots 3/4 Slots 4/5 Slots 5/6 Slots 6/7 Slots 7/8 Slots 8/9 Slots 9/10 Slots 10/11 Slots 11/12 Not Allowed Reserved • DME (Bit 11): DMA Enable. (0 = DMA Disabled or 1 = DMA Enabled) • TFF (Bit 13): Transmit FIFO Full - Read Only. (0 = FIFO Not Full or 1 = FIFO Full) • TFE (Bit 4): Transmit FIFO Empty - Read Only. (0 = FIFO Not Empty or 1 = FIFO Empty) • TU (Bit 15): Transmit Underflow – Sticky, Write 1 Clear. (0 = FIFO Underflow has not occurred or 1 = FIFO Underflow has occurred) System Reset Description Table 25. AC’97 Slot Select Values There are several sources of reset to the ADSP-2192M. Slot Mono Stereo • Power-On Reset 0000–0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101–1111 Reserved Slot 3 Slot 4 Slot 5 Slot 6 Slot 7 Slot 8 Slot 9 Slot 10 Slot 11 Slot 12 Reserved Reserved Slots 3/4 Slots 4/5 Slots 5/6 Slots 6/7 Slots 7/8 Slots 8/9 Slots 9/10 Slots 10/11 Slots 11/12 Not Allowed Reserved • PCI Reset • USB Reset • Soft Reset (RST in CMSR Register) Power-On Reset The DSP has an internal power-on reset circuit that resets the DSP when power is applied. The DSP also has a Power-On Reset PORST signal that can initiate this master reset. Note that PORST is not needed when using PCI or USB (and is shown as a no connect in Figure 7); these interfaces reset the DSP under their control as needed. DSP Software Reset • SMSel (Bit 3): Stereo/Mono Select - AC’97 Mode Only. (0 = Mono Stream or 1 = Stereo Stream) The DSP can generate a software reset using the RSTD bit in DSP Interrupt/Power-down Registers). Generally, reset conditions are handled by forcing the DSPs to execute ROM- or RAM-based Reset Handler code. The Reset Handler that is executed can be dictated by the Reset Source as defined by the CRST[1:0] bits in the Chip Mode/Status Register (CMSR). The exact Reset Functionality is therefore defined by the ROM and RAM Reset Handler Code and as such is programmable. • SLOT (Bits 7–4): AC’97 Slot Select - AC’97 Mode Only. Booting Modes • FIP (Bit 10–8): FIFO interrupt position. An interrupt is generated when FIP[2:0] + 1 words have been received in the FIFO. The interrupt is level-sensitive. The ADSP-2192M has two mechanisms for automatically loading internal program memory after reset. The CRST pins, sampled during power-on reset, implement these modes: • DME (Bit 11): DMA Enable. (0 = DMA Disabled or 1 = DMA Enabled) • Boot from PCI Host The Receive FIFO Control Register has the following bit field definitions: • CE (Bits 1–0): Connection Enable. (00 = Disable, 01 = Reserved, 10 = Connect to AC’97, 11 = Reserved) • DPSel (Bit 2): Reserved (0) REV. 0 • Boot from USB Host –23– ADSP-2192M Optionally, extra boot information can come from an SPI or Microwire serial EPROM during PCI or USB booting. The boot process flow appears in Figure 5. DSP EMERGES FROM RESET AND PROGRAM FLOW JUMPS TO BOOT ROM LOADER KERNEL READS CRST PINS AND DETERMINES MODE OF BOOTING. ALSO PERFORMS HOUSEKEEPING OPERATIONS, SETTING UP INTERRUPTS, ETC. CALL SUBROUTINE TO AUTO-DETECT SERIAL EEPROM LOADER KERNEL READS BUS MODE PINS TO SET UP BUS CONFIGURATION SERIAL EEPROM EXISTS? NO YES DETERMINE 8- OR 16-BIT SPI OR MICROWIRE LOAD SERIAL EEPROM CONFIGURATION AND DATA PACKETS. LOAD PCI/USB CONFIGURATION REGISTERS ACCORDINGLY NO DOES ANY SERIAL EEPROM NEED TO BE EXECUTED? YES TRANSFER CONTROL TO PCI OR USB, TO FACILITATE REST OF BOOT AFTER BOOTING IS COMPLETE, USER HAS OPTION TO RETURN TO SERIAL EEPROM OR JUMP TO USER CODE AND BEGIN EXECUTION EXECUTE PACKETS FINISH Figure 5. Boot Process Flow Power Management Description 2.5 V Regulator Options The ADSP-2192M supports several states with distinct power management and functionality capabilities. These states encompass both hardware and software states. In 5 V and 3.3 V PCI applications the ADSP-2192M 2.5 V IVDD supply will be generated by an on-chip regulator. The internal 2.5 V supply (IVDD) can be generated by the on-chip regulator combined with an external power transistor as shown in Figure 6. To support the PCI specification’s power-down modes, the two transistors control the primary and auxiliary supply. If the reference voltage on RVDD (typically the same as PCIVDD) drops out, the VCTRLAUX will switch on the device connected to PCIVAUX and VCTRLVDD will switch off the primary supply. USB applications may require an external high efficiency switching regulator to generate the 2.5 V supply for the ADSP-2192M. The driver and DSP code take responsibility for detailed power management of the modem, so minimum power levels are achieved regardless of OS or BIOS. In response to events, the driver and DSPs manage power by changing platform states as necessary. Power Regulators The ADSP-2192M is intended to operate in a variety of different systems. These include PCI, CardBus, USB, and embedded (Sub-ISA) applications. The PCI and USB specifications define power consumption limits that constrain the design of the DSP. –24– REV. 0 ADSP-2192M TANTALUM OR ELECTROLYTIC DSP INTERNAL CIRCUIT 2.5V @ 500mA Figure 7. Capacitor values are dependent on crystal type and should be specified by the crystal manufacturer. A parallelresonant, fundamental frequency, microprocessor-grade 24.576 MHz crystal should be used for this configuration. CERAMIC PCI VDD 3.0V – 5.5V IVDD 24.576M Hz 10µF 0.1µF VCTRLVDD ZETEX FZT951 XTALI EXTERNAL COMPONENTS – PCIVAUX 3.0V – 3.6V + CL KSEL 3V OR 5V CL OCK XTALO AD SP-2192M BUS1 BUS SEL ECT BUS0 VREF ZETEX FZT951 POW R ON RESET PORST PCI CLO CK RUN CL KRUN PCI CLO CK CL K PCI RESET RST AC'97 BIT CL OCK BITC LK VCTR LAUX Figure 6. 2.5 V Regulator Options Low Power Operation In addition to supporting the PCI and USB standards’ powerdown modes, additional power-down modes for the DSP cores and peripheral buses are supported by the ADSP-2192M. The power-down modes are controlled by the DSP1 and DSP2 Interrupt/Power-down registers. Figure 7. External Crystal Connections Clock Signals The ADSP-2192M can be clocked by a crystal oscillator. If a crystal oscillator is used, the crystal should be connected across the XTALI/O pins, with two capacitors connected as shown in 12.0MHz USB PORT USB 1/8.192 PLL AND CLOCK CLOCK RECOVERY DOMAIN 33MHz PCI CLK X4 PLL PCI CLOCK 49.152MHz 24.576MHz XTALI 1/2 X6 (SUB-ISA MODE) 147.456MHz DSP CLOCK DOMAIN PLL 49.152MHz (PROGRAMMABLE) 1/2 1/2 PERIPHERAL DEVICE CONTROL BUS CLOCK DOMAIN 12.288 MHz AC’97 CLOCK DOMAIN BITCLK Figure 8. Clock Domains REV. 0 –25– DOMAIN ADSP-2192M Debugging both C/C++ and assembly programs with the VisualDSP++ debugger, programmers can: Instruction Set Description The ADSP-2192M assembly language instruction set has an algebraic syntax that was designed for ease of coding and readability. The assembly language, which takes full advantage of the processor’s unique architecture, offers the following benefits: • View mixed C/C++ and assembly code (interleaved source and object information) • Insert break points • ADSP-219x assembly language syntax is a superset of and source code compatible (except for two data registers and DAG base address registers) with ADSP-218x family syntax. Existing 218x programs may need to be restructured, however, to accommodate the ADSP-2192M’s unified memory space and to conform to its interrupt vector map. • Set conditional breakpoints on registers, memory, and stacks • Trace instruction execution • Perform linear or statistical profiling of program execution • Fill, dump, and graphically plot the contents of memory • The algebraic syntax eliminates the need to remember cryptic assembler mnemonics. For example, a typical arithmetic add instruction, such as AR = AX0 + AY0, resembles a simple equation. • Source level debugging • Create custom debugger windows The VisualDSP++ IDE lets programmers define and manage DSP software development. Its dialog boxes and property pages let programmers configure and manage all of the ADSP-219x development tools, including the syntax highlighting in the VisualDSP++ editor. This capability permits: • Every instruction, except two, assembles into a single, 24-bit word that can execute in a single instruction cycle. The exceptions are two dual-word instructions, one of which writes 16- or 24-bit immediate data to memory, and the other of which jumps/calls to other pages in memory. • Control how the development tools process inputs and generate outputs. • Multifunction instructions allow parallel execution of an arithmetic, MAC, or shift instruction with up to two fetches or one write to processor memory space during a single instruction cycle. • Maintain a one-to-one correspondence with the tool’s command line switches. Analog Devices DSP emulators use the IEEE 1149.1 JTAG test access port of the ADSP-2192M processor to monitor and control the target board processor during emulation. The emulator provides full-speed emulation, allowing inspection and modification of memory, registers, and processor stacks. Nonintrusive in-circuit emulation is assured by the use of the processor’s JTAG interface—the emulator does not affect target system loading or timing. • Supports a wider variety of conditional and unconditional jumps and calls, and a larger set of conditions on which to base execution of conditional instructions. Development Tools The ADSP-2192M is supported with a complete set of software and hardware development tools, including Analog Devices emulators and VisualDSP++® development environment. The same emulator hardware that supports other ADSP-219x DSPs, also fully emulates the ADSP-2192M. The VisualDSP++ project management environment lets programmers develop and debug an application. This environment includes an easy to use assembler that is based on an algebraic syntax; an archiver (librarian/library builder), a linker, a loader, a cycle-accurate instruction-level simulator, a C/C++ compiler, and a C/C++ runtime library that includes DSP and mathematical functions. Two key points for these tools are: • Compiled ADSP-219x C/C++ code efficiency—the compiler has been developed for efficient translation of C/C++ code to ADSP-219x assembly. The DSP has architectural features that improve the efficiency of compiled C/C++ code. • ADSP-218x family code compatibility—The assembler has legacy features to ease the conversion of existing ADSP-218x applications to the ADSP-219x. In addition to the software and hardware development tools available from Analog Devices, third parties provide a wide range of tools supporting the ADSP-219x processor family. Hardware tools include ADSP-219x PC plug-in cards. Third party software tools include DSP libraries, real-time operating systems, and block diagram design tools. Designing an Emulator-Compatible DSP Board (Target) The White Mountain DSP (Product Line of Analog Devices, Inc.) family of emulators are tools that every DSP developer needs to test and debug hardware and software systems. Analog Devices has supplied an IEEE 1149.1 JTAG Test Access Port (TAP) on each JTAG DSP. The emulator uses the TAP to access the internal features of the DSP, allowing the developer to load code, set breakpoints, observe variables, observe memory, and examine registers. The DSP must be halted to send data and commands, but once an operation has been completed by the emulator, the DSP system is set running at full speed with no impact on system timing. To use these emulators, the target’s design must include the interface between an Analog Devices JTAG DSP and the emulation header on a custom DSP target board. VisualDSP++ is a registered trademark of Analog Devices, Inc. –26– REV. 0 ADSP-2192M Target Board Header The emulator interface to an Analog Devices JTAG DSP is a 14-pin header, as shown in Figure 9. The customer must supply this header on the target board in order to communicate with the emulator. The interface consists of a standard dual row 0.025" square post header, set on 0.1" 0.1" spacing, with a minimum post length of 0.235". Pin 3 is the key position used to prevent the pod from being inserted backwards. This pin must be clipped on the target board. GND 1 2 3 5 GND 5 6 TMS 7 8 BTCK EMU BTDI GND GND TCK 9 10 11 12 TRST TDI 13 14 TDO TOP VIEW TMS 8 BTCK Figure 10. JTAG Target Board Connector with No Local Boundary Scan TCK 9 4 EMU 6 BTMS 7 3 BTMS 4 KEY (NO PIN) 2 KEY (NO PIN) BTRST GND 1 10 BTRST TRST 11 12 BTDI TDI 13 14 GND TDO TOP VIEW Figure 9. JTAG Target Board Connector for JTAG Equipped Analog Devices DSP (Jumpers in Place) 0.64" Also, the clearance (length, width, and height) around the header must be considered. Leave a clearance of at least 0.15" and 0.10" around the length and width of the header, and reserve a height clearance to attach and detach the pod connector. 0.88" 0.24" As can be seen in Figure 9, there are two sets of signals on the header. There are the standard JTAG signals TMS, TCK, TDI, TDO, TRST, and EMU used for emulation purposes (via an emulator). There are also secondary JTAG signals BTMS, BTCK, BTDI, and BTRST that are optionally used for boardlevel (boundary scan) testing. Figure 11. JTAG Pod Connector Dimensions 0.10" When the emulator is not connected to this header, place jumpers across BTMS, BTCK, BTRST, and BTDI as shown in Figure 10. This holds the JTAG signals in the correct state to allow the DSP to run free. Remove all the jumpers when connecting the emulator to the JTAG header. 0.15" Figure 12. JTAG Pod Connector Keep-Out Area JTAG Emulator Pod Connector Design-for-Emulation Circuit Information Figure 11 details the dimensions of the JTAG pod connector at the 14-pin target end. Figure 12 displays the keep-out area for a target board header. The keep-out area allows the pod connector to properly seat onto the target board header. This board area should contain no components (such as chips, resistors, capacitors). The dimensions are referenced to the center of the 0.25" square post pin. For details on target board design issues including: single processor connections, multiprocessor scan chains, signal buffering, signal termination, and emulator pod logic, see the EE-68: Analog Devices JTAG Emulation Technical Reference on the Analog Devices website (www.analog.com)—use site search on “EE-68.” This document is updated regularly to keep pace with improvements to emulator support. REV. 0 –27– ADSP-2192M Additional Information This data sheet provides a general overview of the ADSP-2192M architecture and functionality. For detailed information on the ADSP-219x Family core architecture and instruction set, refer to the ADSP-219x/2191 DSP Hardware Reference. Table 27. Pin Configurations: PCI/USB Bus Interface (continued) PIN DESCRIPTIONS ADSP-2192M pin definitions are listed in a series of tables following this section. Inputs identified as synchronous (S) must meet timing requirements with respect to CLKIN (or with respect to TCK for TMS, TDI). Inputs identified as asynchronous (A) can be asserted asynchronously to CLKIN (or to TCK for TRST). The following symbols appear in the Type columns of these tables: G = Ground, I = Input, O = Output, P = Power Supply, and T = Three-State. Table 27. Pin Configurations: PCI/USB Bus Interface Pin Name LQFP I/O Description AD0 AD1 AD2 AD3 AD4 AD5 AD6 AD7 AD8 AD9 AD10 AD11 AD12 AD13 AD14 AD15 AD16 AD17 AD18 AD19 AD20 AD21 AD22 AD23 AD24 AD25 AD26 AD27 AD28 AD29 AD30 AD31 CBE0 57 56 55 54 53 48 47 46 44 43 42 37 36 35 34 33 15 14 13 12 11 8 7 6 3 2 143 142 141 138 137 136 45 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 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 I/O CBE1 32 I/O Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus Addr/Data Bus PCI Cmd/Byte Enable PCI Cmd/Byte Enable Pin Name LQFP I/O Description CBE2 16 I/O CBE3 4 I/O CLK CLKRUN DEVSEL FRAME GNT IDSEL INTAB IRDY PAR PCIGND I O I/O I/O I I O I/O I/O I I PCI VDD supply PERR 130 26 24 17 131 5 128 22 31 1, 10, 21, 30, 39, 52, 133 9, 18, 29, 38, 51, 132, 144 27 PCI Cmd/Byte Enable PCI Cmd/Byte Enable PCI Clock Clock Run PCI Target Select PCI Frame Select Grant PCI Initiator Select PCI/ISA Interrupt PCI Initiator Ready PCI Bus Parity PCI Ground I/O PME 135 O REQ RST SERR 134 129 28 O I O STOP TRDY 25 23 I/O I/O PCI Parity Error/ USB– (Inverting Input) PCI Power Management Event Request PCI Reset PCI System Error/ USB+ (Noninverting Input) PCI Target Stop PCI Target Ready PCIVDD Table 28. Pin Configurations: Analog Pins –28– Pin Name LQFP I/O Description AGND AQGND CTRLAUX CTRLVDD IVDD NC NC NC RVAUX RVDD 67 68 61 63 62 66 69 70 60 64 I I I I I O I I I I Analog Gnd. Ref. Analog Gnd. X Supply Control VDD Digital VDD No Connect No Connect No Connect X Supply Analog VDD Supply REV. 0 ADSP-2192M Table 29. Pin Configurations: Emulator Pins Table 33. Pin Configurations: IO Pins Pin Name LQFP I/O Description Pin Name LQFP I/O Description EMU TCK 74 78 O I TDI TDO 80 81 I O TMS 75 I TRST 79 I Emulator Event Pin Emulator Clock Input Emulator Data Input Emulator Data Output Emulator Mode Select Emulator Logic Reset AIOGND IO0 IO1 IO2 IO3 IO4 IO5 IO6 IO7 IOVDD 76, 91 82 83 84 86 87 88 89 90 77, 85 I/O I/O I/O I/O I/O I/O I/O I/O IO Ground IO Pin, Bit 0 IO Pin, Bit 1 IO Pin, Bit 2 IO Pin, Bit 3 IO Pin, Bit 4 IO Pin, Bit 5 IO Pin, Bit 6 IO Pin, Bit 7 IO VDD Table 30. Pin Configurations: Crystal/Configuration Pins Table 34. Pin Configurations: Power Supply Pins Pin Name LQFP I/O Description Pin Name LQFP BUS0 124 I BUS1 123 I CLKSEL IGND NC PORST XTALI 116 122 127 121 118 I/O I O I I ACVAUX AIOGND AVDD CTRLAUX CTRLVDD IGND XTALO 119 I/O PCI/Sub-ISA/ CardBus Select Pins PCI/ Sub-ISA/ CardBus Select Pins Clock Select IGND No Connect Power-On Reset Crystal Input Pin (24.576 MHz) Crystal Output Pin 92 91 65 61 63 20, 41, 50, 59, 104, 120, 122, 126, 139 19, 40, 49, 58, 62, 103, 117, 125, 140 60 64 Table 31. Pin Configurations: AC’97 Interface Pins Pin Name LQFP I/O Description ACRST ACVAUX ACVDD BITCLK SDI0 102 92 93 96 99 O I I I I SDI1 98 I SDI2 97 I SDO 100 O SYNC 101 O AC’97 Reset AC’97 VAUX Input AC’97 VDD Input AC’97 Bit Clock AC’97 Serial Data Input, Bit 0 AC’97 Serial Data Input, Bit 1 AC’97 Serial Data Input, Bit 2 AC’97 Serial Data Output AC’97 Sync IVDD RVAUX RVDD Table 32. Pin Configurations: Serial EEPROM Pins Pin Name LQFP I/O Description SCK 72 I SDA SEN 71 73 I I Serial EEPROM Clock Serial EEPROM Data Serial EEPROM Enable REV. 0 –29– I/O Description AC’97 VAUX Input IO Ground Analog VDD Supply AUX Control Control VDD Digital Ground Digital VDD AUX Supply Analog VDD Supply ADSP-2192M SPECIFICATIONS RECOMMENDED OPERATING CONDITIONS K Grade Parameter 1 VDDINT VDDEXT2 VDDEXT3 VIH1 VIH2 VIL1 VIL2 TAMB Test Conditions Internal Supply Voltage External Supply Voltage Option 3.3 V (All Supplies) External Supply Voltage Option 5.0 V (VDDEXT Supplies only) High Level Input Voltage4 High Level Input Voltage5 Low Level Input Voltage2 Low Level Input Voltage6 Ambient Operating Temperature @ VDDEXT = Max @ VDDEXT = Max @ VDDEXT = Min @ VDDINT = Min Min Max Unit 2.38 3.0 2.62 3.6 V V 4.75 5.25 V 2.0 0.65 VDDEXT –0.3 –0.3 0 VDDEXT VDDEXT 0.8 0.4 70 V V V V °C Specifications subject to change without notice. 1V = IVDD. = IOVDD, PCIVDD, ACVDD, RVDD, RVAUX, ACVAUX. 3V DDEXT = IOVDD, PCIVDD, ACVDD, RVDD only. 4 Applies to PCI input and bidirectional pins. 5 Applies to I/O bus bidirectional pins. 6 Applies to input pins XTALI, BUS0, BUS1. 2V DDINT DDEXT ELECTRICAL CHARACTERISTICS Parameter VOH VOL IIH IIL IILP IOZH IOZL IDD 1 IDD-IDLE CIN High Level Output Voltage Low Level Output Voltage1 High Level Input Current2, 3 Low Level Input Current2 Low Level Input Current3 Three-State Leakage Current4, 5 Three-State Leakage Current4 Supply Current Dynamic (Internal)6 Supply Current (Idle) Input Capacitance7, 8 IDD–Power-Down Supply Current (Power-Down) Test Conditions Min @ VDDEXT = min, IOH = –0.5 mA @ VDDEXT = max, IOL = 2.0 mA @ VDDEXT = max, VIN = VDD max @ VDDEXT = max, VIN = 0 V @ VDDEXT = max, VIN = 0 V @ VDDEXT = max, VIN = VDD max @ VDDEXT = max, VIN = 0 V @ 160 MHz VDDINT = 2.5 V 2.4 VDDINT = 2.5 V fIN =1 MHz, TAMB = 25°C, VDDINT = 2.5 V TAMB = 25°C, VDDINT = 2.5 V Typ Max Unit 0.4 10 10 250 10 10 V V µA µA µA µA µA mA 340 45 20 0.8 mA pF mA Specifications subject to change without notice. 1 Applies to output and bidirectional pins. Applies to input. 3 Applies to input pins with internal pull-ups: EMS, EDI, ERSTB, SDA, SEN, SCR, BUS0, BUS1. 4 Applies to three-statable pins. 5 Applies to three-statable pins with internal pull-ups. 6 DSP typical operating condition for supply current specification. DSP MACs, ALUs, and shifts 50%; data read/write/moves 30%, idle 20%. 7 Applies to all signal pins. 8 Guaranteed, but not tested. 2 –30– REV. 0 ADSP-2192M ABSOLUTE MAXIMUM RATINGS Power Supply, Internal (VDDINT)1 . . . . . . . . –0.3 V to +6.0 V Power Supply, External (VDDEXT) . . . . . . . –0.3 V to +6.0 V Input Voltage (Signal Pins) . . . . . . –0.3 V to VDDEXT + 0.3 V TSTORE Storage Temperature Range . . . . . .–65ºC to +150ºC TLEAD Lead Temperature (5 seconds) max . . . . . . . . . 185ºC 1 Stresses greater than those listed above may cause permanent damage to the device. These are stress ratings only; functional operation of the device at these or any other conditions greater than those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ESD SENSITIVITY CAUTION ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on the human body and test equipment and can discharge without detection. Although the ADSP-2192M features proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance degradation or loss of functionality. TIMING SPECIFICATIONS This section contains timing information for the DSP’s external signals. Programmable Flags Cycle Timing Table 35 and Figure 13 describe Programmable Flag operations. The signals indicated are asynchronous and are not tied to any clock. Table 35. Programmable Flags Cycle Timing Parameter tGPTW tXTALIHI tXTALILO tENABLE tDISABLE Min GPIO Timing Pulsewidth XTALI High Pulsewidth XTALI Low Pulsewidth I/O Pins I/O Pins Unit 10 ns ns ns ns ns 40 10 15 0 CLK tDISABLE tENABLE FLAG I/O PINS Figure 13. Programmable Flags Cycle Timing REV. 0 Max –31– ADSP-2192M Sub-ISA Interface Read/Write Cycle Timing Table 36, Figure 14, and Figure 15 describe Sub-ISA Interface Read and Write operations. Table 36. Sub-ISA Interface Read/Write Cycle Timing Parameter tISTW tICYC tAESU tAEHD tADSU tADHD tDHD1 tDHD2 tRDDV tWDSU tRDY1 tRDY2 Min IOR/IOW Strobe Width IOR/IOW Cycle Time AEN Setup to IOR/IOW Falling AEN Hold from IOR/IOW Rising Address Setup to IOR/IOW Falling Address Hold from IOR/IOW Rising Data Hold from IOR Rising Data Hold from IOW Rising IOR Falling to Valid Read Data Write Data Setup to IOW Rising IOR/IOW Rising from IOCHRDY Rising IOCHRDY Falling from IOR/IOW Rising Max 100 240 10 0 10 0 20 15 40 10 0 20 Unit ns ns ns ns ns ns ns ns ns ns ns ns AEN tAESU tRDY2 tRDY1 tAEHD IOCHRDY tICYC IOR tRDDV tISTW tDHD1 ISAD15–0 tADHD tADSU ISAA3–1 Figure 14. Sub-ISA Interface Read Cycle Timing –32– REV. 0 ADSP-2192M AEN tAESU tRDY2 tRDY1 tAEHD IOCHRDY tICYC IOW tSTW tWDSU tDHD2 ISAD15–0 tADHD tADSU ISAA3–1 Figure 15. Sub-ISA Interface Write Cycle Timing REV. 0 –33– ADSP-2192M Output Drive Currents Power Dissipation Figure 16 shows typical I-V characteristics for the output drivers of the ADSP-2192M. The curves represent the current drive capability of the output drivers as a function of output voltage. Total power dissipation has two components, one due to internal circuitry and one due to the switching of external output drivers. Internal power dissipation is dependent on the instruction execution sequence and the data operands involved. The external component of total power dissipation is caused by the switching of output pins. Its magnitude depends on: 80 VDD EXT = 5.0V @ 25°C SOURCE (VDDEXT) CURRENT – mA 60 • Number of output pins that switch during each cycle (O) • The maximum frequency at which they can switch (f) VDDEXT = 3.3V @ 25°C 40 20 • Their load capacitance (C) OUTPUT CURRENT • Their voltage swing (VDD) VOH 0 and is calculated by the formula below. –20 VOL VDDEXT = 3.3V @ 25°C 2 P EXT = O × C × V DD × f –40 –60 The load capacitance includes the processor’s package capacitance (CIN). The switching frequency includes driving the load high and then back low. Address and data pins can drive high and low at a maximum rate of 33 MHz. VDD EX T = 5.0V @ 25°C –80 INPUT CURRENT –100 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 SOURCE (VDDEXT) VOLTAGE – V The PEXT equation is calculated for each class of pins that can drive as shown in Table 37. Figure 16. Typical Drive Currents Table 37. PEXT Calculation Example Pin Type No. of Pins % Switching C f VDD2 = PEXT Address/Data DEVSEL CBE CLK 32 1 1 1 10 pF 10 pF 10 pF 10 pF 33 MHz 33 MHz 33 MHz 33 MHz 10.9 V 10.9 V 10.9 V 10.9 V = 0.115 W = 0.0 W = 0.003 W = 0.003 W PEXT =0.04687 W 100 0 100 100 Output Disable Time A typical power consumption can now be calculated for these conditions by adding a typical internal power dissipation with the following formula. Output pins are considered to be disabled when they stop driving, go into a high impedance state, and start to decay from their output high or low voltage. The time for the voltage on the bus to decay by ∆V is dependent on the capacitive load, CL and the load current, IL. This decay time can be approximated by the equation below. P TOTAL = P EXT + P INT Where: • PEXT is from Table 37 C L ∆V t DECAY = --------------IL • PINT is IDDINT 2.5 V, using the calculation IDDINT listed in Electrical Characteristics on Page 30. Note that the conditions causing a worst-case PEXT are different from those causing a worst-case PINT. Maximum PINT cannot occur while 100% of the output pins are switching from all ones to all zeros. Note also that it is not common for an application to have 100% or even 50% of the outputs switching simultaneously. Test Conditions The ADSP-2192M is tested for compliance with all support industry standard interfaces (PCI, USB, and AC’97). Also, the DSP is tested for output enable, disable, and pulsewidth. See Table 35 for the values of these parameters. The output disable time tDIS is the difference between tMEASURED and tDECAY as shown in Figure 17. The time tMEASURED is the interval from when the reference signal switches to when the output voltage decays ∆V from the measured output high or output low voltage. The tDECAY is calculated with test loads CL and IL, and with ∆V equal to 0.5 V. Output Enable Time Output pins are considered to be enabled when they have made a transition from a high impedance state to when they start driving. The output enable time tENA is the interval from when a reference signal reaches a high or low voltage level to when the –34– REV. 0 ADSP-2192M INPUT OR O UTPUT REFERENCE SIGNAL tMEASURED tDIS 1.5V 1.5V Figure 19. Voltage Reference Levels for AC Measurements (Except Output Enable/Disable) tENA VOH (MEASURED) VOH (MEASURED) – V 2.0V VOL (MEASURED) + V 1.0V VOL (MEASURED) tDECAY OUTPUT STOPS DRIVING OUTPUT STARTS DRIVING HIGH IMPEDANCE STATE. TEST CONDITIONS CAUSE THIS VOLTAGE TO BE APPROXIMATELY 1.5V Figure 17. Output Enable/Disable IOL output has reached a specified high or low trip point, as shown in the Output Enable/Disable diagram (Figure 17). If multiple pins (such as the data bus) are enabled, the measurement value is that of the first pin to start driving. Example System Hold Time Calculation To determine the data output hold time in a particular system, first calculate tDECAY using the equation at Output Disable Time on Page 34. Choose ∆V to be the difference between the ADSP2192M’s output voltage and the input threshold for the device requiring the hold time. A typical ∆V will be 0.4 V. CL is the total bus capacitance (per data line), and IL is the total leakage or threestate current (per data line). The hold time will be tDECAY plus the minimum disable time (i.e., tDATRWH for the write cycle). Capacitive Loading TO OUTPUT PIN 1.5V 50pF Output delays and holds are based on standard capacitive loads: 50 pF on all pins. The delay and hold specifications given should be derated for loads other than the nominal value of 50 pF. Environmental Conditions IOH Figure 18. Equivalent Device Loading for AC Measurements (Includes All Fixtures) REV. 0 The thermal characteristics in which the DSP is operating influence performance (see Table 38). Table 38. Thermal Characteristics –35– Rating Description Symbol LQFP Thermal Resistance (Junction-to-Ambient) θJA 33.79°C/W Still Air ADSP-2192M 144-Lead LQFP Pinout Table 39 lists the LQFP pinout by signal name. Table 40 lists the LQFP pinout by pin number. Table 39. 144-Lead LQFP Pins (Alphabetically by Signal) Signal Pin No. Signal Pin No. Signal Pin No. Signal Pin No. ACRST ACVAUX ACVDD AD0 AD1 AD2 AD3 AD4 AD5 AD6 AD7 AD8 AD9 AD10 AD11 AD12 AD13 AD14 AD15 AD16 AD17 AD18 AD19 AD20 AD21 AD22 AD23 AD24 AD25 102 92 93 57 56 55 54 53 48 47 46 44 43 42 37 36 35 34 33 15 14 13 12 11 8 7 6 3 2 AD26 AD27 AD28 AD29 AD30 AD31 AGND AIOGND AQGND AVDD ACVAUX ACVDD BITCLK BUS0 BUS1 CBE0 CBE1 CBE2 CBE3 CLK CLKRUN CLKSEL CTRLAUX CTRLVDD DEVSEL EMU FRAME GND GNT 143 142 141 138 137 136 67 91 68 65 113 112 96 124 123 45 32 16 4 130 26 116 61 63 24 74 17 111 131 IDSEL IGND IGND IGND IGND IGND IGND IGND IGND IGND INTAB IO0 IO1 IO2 IO3 IO4 IO5 IO6 IO7 IOGND IOVDD IOVDD IRDY IVDD IVDD IVDD IVDD IVDD IVDD 5 20 41 50 59 104 120 122 126 139 128 82 83 84 86 87 88 89 90 76 77 85 22 19 40 49 58 103 117 IVDD IVDD IVDD NC NC NC NC NC NC NC NC NC NC NC NC NC NC PAR PCIGND PCIGND PCIGND PCIGND PCIGND PCIGND PCIGND PCIVDD PCIVDD PCIVDD PCIVDD 125 140 62 115 114 108 105 109 107 106 110 127 70 66 94 69 95 31 1 10 21 30 39 52 133 9 18 29 38 –36– Signal Pin No. PCIVDD PCIVDD PCIVDD PERR PME PORST REQ RST RVAUX RVDD SCK SDA SDI0 SDI1 SDI2 SDO SEN SERR STOP SYNC TCK TDI TDO TMS TRDY TRST XTALI XTALO 51 132 144 27 135 121 134 129 60 64 72 71 99 98 97 100 73 28 25 101 78 80 81 75 23 79 118 119 REV. 0 ADSP-2192M Table 40. 144-Lead LQFP Pins (Numerically by Pin Number) Pin No. Signal Pin No. Signal Pin No. Signal Pin No. Signal 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 PCIGND AD25 AD24 CBE3 IDSEL AD23 AD22 AD21 PCIVDD PCIGND AD20 AD19 AD18 AD17 AD16 CBE2 FRAME PCIVDD IVDD IGND PCIGND IRDY TRDY DEVSEL STOP CLKRUN PERR SERR PCIVDD 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 PCIGND PAR CBE1 AD15 AD14 AD13 AD12 AD11 PCIVDD PCIGND IVDD IGND AD10 AD9 AD8 CBE0 AD7 AD6 AD5 IVDD IGND PCIVDD PCIGND AD4 AD3 AD2 AD1 AD0 IVDD 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 IGND RVAUX CTRLAUX IVDD CTRLVDD RVDD AVDD NC AGND AQGND NC NC SDA SCK SEN EMU TMS IOGND IOVDD TCK TRST TDI TDO IO0 IO1 IO2 IOVDD IO3 IO4 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 IO5 IO6 IO7 AIOGND ACVAUX ACVDD NC NC BITCLK SDI2 SDI1 SDI0 SDO SYNC ACRST IVDD IGND NC NC NC NC NC NC GND ACVDD ACVAUX NC NC CLKSEL REV. 0 –37– Pin No. Signal 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 IVDD XTALI XTALO IGND PORST IGND BUS1 BUS0 IVDD IGND NC INTAB RST CLK GNT PCIVDD PCIGND REQ PME AD31 AD30 AD29 IGND IVDD AD28 AD27 AD26 PCIVDD ADSP-2192M OUTLINE DIMENSIONS 144-Lead Plastic Quad Flatpack [LQFP] (ST-144) 22.00 BSC SQ 20.00 BSC SQ 109 144 108 1 PIN 1 INDICATOR 0.50 BSC TYP (LEAD PITCH) 0.27 0.22 TYP 0.17 SEATING PLANE 0.08 MAX (LEAD COPLANARITY) 0.15 0.05 1.45 1.40 1.35 0.75 0.60 TYP 0.45 73 36 72 37 1.60 MAX DETAIL A DETAIL A TOP VIEW (PINS DOWN) NOTES: 1. DIMENSIONS ARE IN MILLIMETERS AND COMPLY WITH JEDEC STANDARD MS-026-BFB. 2. ACTUAL POSITION OF EACH LEAD IS WITHIN 0.08 OF ITS IDEAL POSITION, WHEN MEASURED IN THE LATERAL DIRECTION. 3. CENTER DIMENSIONS ARE NOMINAL. ORDERING GUIDE Part Number1 Ambient Temperature Instruction Range Rate ADSP-219212MKST160 0ºC to 70ºC 1 160 MHz On-Chip SRAM Package Description Operating Voltage 2.4 Mbit 144-Lead LQFP 2.5 Int./3.3 or 5 Ext. V ST = Plastic Quad Flatpack (LQFP). –38– REV. 0 –39– –40– PRINTED IN U.S.A. C02566–0–11/02(0)