0
登录后你可以
  • 下载海量资料
  • 学习在线课程
  • 观看技术视频
  • 写文章/发帖/加入社区
会员中心
创作中心
发布
  • 发文章

  • 发资料

  • 发帖

  • 提问

  • 发视频

创作活动
79R3041-25J

79R3041-25J

  • 厂商:

    IDT

  • 封装:

  • 描述:

    79R3041-25J - INTEGRATED RISController™ FOR LOW-COST SYSTEMS - Integrated Device Technology

  • 数据手册
  • 价格&库存
79R3041-25J 数据手册
IDT79R3041™ INTEGRATED RISController™ FOR LOW-COST SYSTEMS Integrated Device Technology, Inc. IDT79R3041 IDT79RV3041 FEATURES: • Instruction set compatible with IDT79R3000A and RISController Family MIPS RISC CPUs • High level of integration minimizes system cost — RISC CPU — Multiply/divide unit — Instruction Cache — Data Cache — Programmable bus interface — Programmable port width support • On-chip instruction and data caches — 2KB of Instruction Cache — 512B of Data Cache • Flexible bus interface allows simple, low-cost designs — Superset pin-compatible with RISController — Adds programmable port width interface (8-, 16-, and 32-bit memory sub-regions) — Adds programmable bus interface timing support (Extended address hold, Bus turn around time, Read/write masks) ClkIn Clock Generator Unit • • • • • • • • • • • Double-frequency clock input 16.67MHz, 20MHz, 25MHz and 33MHz operation 20MIPS at 25MHz Low cost 84-pin PLCC packaging On-chip 4-deep write buffer eliminates memory write stalls On-chip 4-word read buffer supports burst or simple block reads On-chip DMA arbiter On-chip 24-bit timer Boot from 8-bit, 16-bit, or 32-bit wide PROMs Pin- and software-compatible family includes R3041, R3051, R3052™, and R3081™ Complete software support — Optimizing compilers — Real-time operating systems — Monitors/debuggers — Floating Point emulation software — Page Description Languages Master Pipeline Control System Control Coprocessor Exception/Control Registers Bus Interface Registers PortSize Register Counter Registers 32 Physical Address Bus SBrCond(3:2) Int(5:3), SInt(2:0) TC Integer CPU Core General Registers (32 x 32) ALU Shifter Mult/Div Unit Address Adder PC Control Virtual Address 32 Instruction Cache 2kB Data Bus R3051 Superset Bus Interface Unit 4-deep Write Buffer Data Unpack Unit Address/ Data 4-deep Read Buffer Data Pack Unit DMA Ctrl DMA Arbiter BIU Control Data Cache 512B Timing/ Interface Control Rd/Wr SysClk 2905 drw 01 Ctrl Figure 1. R3041 Block Diagram RISController, R3041, R3051, R3052, R3081, ORION, IDT/sim, and IDT/kit are trademarks, and the IDT logo is a registered trademark of Integrated Device Technology, Inc. COMMERCIAL TEMPERATURE RANGE ©1996 Integrated Device Technology, Inc. December 2008 DSC-2905/5 1 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE INTRODUCTION The IDT RISController family is a series of high-performance 32-bit microprocessors featuring a high-level of integration, and targeted to high-performance but cost sensitive embedded processing applications. The RISController family is designed to bring the high-performance inherent in the MIPS RISC architecture into low-cost, simplified, power sensitive applications. Thus, functional units have been integrated onto the CPU core in order to reduce the total system cost, rather than to increase the inherent performance of the integer engine. Nevertheless, the RISController family is able to offer 35MIPS of integer performance at 40MHz without requiring external SRAM or caches. Further, the RISController family brings dramatic power reduction to these embedded applications, allowing the use of low-cost packaging. Thus, the RISController family allows customer applications to bring maximum performance at minimum cost. The R3041 extends the range of price/performance achievDevice Name R3051 R3052 R3071 R3081 R3041 Instruction Cache 4kB 8kB 16kB or 8kB 2kB Data Cache 2kB 2kB 4kB or 8kB 512B able with the RISController family, by dramatically lowering the cost of using the MIPS architecture. The R3041 is designed to achieve minimal system and components cost, yet maintain the high-performance inherent in the MIPS architecture. The R3041 also maintains pin and software compatibility with the RISController and R3081. The RISController family offers a variety of price/performance features in a pin-compatible, software compatible family. Table 1 provides an overview of the current members of the RISController family. Note that the R3051, R3052, and R3081 are also available in pin-compatible versions that include a full-function memory management unit, including 64-entry TLB. The R3051/2 and R3081 are described in separate manuals and data sheets. Figure 1 shows a block level representation of the functional units within the R3041. The R3041 can be viewed as the embodiment of a discrete solution built around the R3000A. By integrating this functionality on a single chip, dramatic cost and power reductions are achieved. An overview of these blocks is presented here, followed with detailed information on each block. Bus Options Mux’ed A/D Mux’ed A/D 1/2 frequency bus option 8-, 16-, and 32-bit port width support 2905 tbl 01 Floating Point Software Emulation Software Emulation On-chip Hardware Software Emulation Programmable timing support Table 1. Pin-Compatible RISController Family CPU Core The CPU core is a full 32-bit RISC integer execution engine, capable of sustaining close to a single cycle execution rate. The CPU core contains a five stage pipeline, and 32 orthogonal 32-bit registers. The RISController family implements the MIPS-I Instruction Set Architecture (ISA). In fact, the execution engine of the R3041 is the same as the execution engine of the R3000A. Thus, the R3041 is binary compatible with those CPU engines, as well as compatible with other members of the RISController family. I#1 IF I#2 RD IF I#3 ALU MEM RD IF I#4 The execution engine of the RISController family uses a five-stage pipeline to achieve close to single cycle execution. A new instruction can be started in every clock cycle; the execution engine actually processes five instructions concurrently (in various pipeline stages). The five parts of the pipeline are the Instruction Fetch, Read register, ALU execution, Memory, and Write Back stages. Figure 2 shows the concurrency achieved by the RISController family pipeline. WB WB WB WB WB ALU MEM RD IF I#5 ALU MEM RD IF ALU MEM RD ALU MEM Current CPU Cycle Figure 2. RISController Family 5-Stage Pipeline 2905 drw 02 2 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE System Control Co-Processor The R3041 also integrates on-chip a System Control Coprocessor, CP0. CP0 manages the exception handling capability of the R3041, the virtual to physical address mapping of the R3041, and the programmable bus interface capabilities of the R3041. These topics are discussed in subsequent sections. The R3041 does not include the optional TLB found in other members of the RISController family, but instead performs the same virtual to physical address mapping of the base version of the RISController family. These devices still support distinct kernel and user mode operation, but do not require page management software or an on-chip TLB, leading to a simpler software model and a lower-cost processor. The memory mapping used by these devices is illustrated in Figure 3. Note that the reserved address spaces shown are for compatibility with future family members; in the current family members, references to these addresses are translated in the same fashion as their respective segments, with no traps or exceptions taken. When using the base versions of the architecture, the system designer can implement a distinction between the user tasks and the kernel tasks, without having to execute page management software. This distinction can take the form of physical memory protection, accomplished by adVIRTUAL 0xffffffff 0xfff00000 0xffefffff Kernel Reserved 1MB Kernel Cached (kseg2) 0xc0000000 0xbfffffff Kernel Uncached (kseg1) Kernel Cached (kseg0) User Reserved 1MB dress decoding, or in other system specific forms. In systems which do not wish to implement memory protection, and wish to have the kernel and user tasks operate out of a single unified memory space, upper address lines can be ignored by the address decoder, and thus all references will be seen in the lower gigabyte of the physical address space. The R3041 adds additional resources into the on-chip CP0. These resources are detailed in the R3041 User's Manual. They allow kernel software to directly control activity of the processor internal resources and bus interface, and include: • Cache Configuration Register: This register controls the data cache block size and miss refill algorithm. • Bus Control Register: This register controls the behavior of the various bus interface signals. • Count and Compare Registers: Together, these two registers implement a programmable 24-bit timer, which can be used for DRAM refresh or as a general purpose timer. • Port Size Control Register: This register allows the kernel to indicate the port width of reads and writes to various subregions of the physical address space. Thus, the R3041 can interface directly with 8-, 16-, and 32-bit memory ports, including a mix of sizes, for both instruction and data references, without requiring additional external logic. PHYSICAL Kernel Reserved 1MB Kernel Cached Tasks 1023 MB 0xc0000000 0xbfffffff 0xbff00000 0xbfefffff 0xffffffff 0xfff00000 0xffefffff User Reserved 1MB 0xa0000000 0x9fffffff 0x80000000 0x7fffffff 0x7ff00000 0x7fefffff Kernel/User Cached Tasks 2047 MB Kernel/User Cached (kuseg) Inaccessible 512 MB Kernel Boot and I/O 0x00000000 512 MB Figure 3. Virtual to Physical Mapping of Base Architecture Versions 0x40000000 0x3fffffff 0x20000000 0x1fffffff 0x00000000 2905 drw 03 3 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE Clock Generation Unit The R3041 is driven from a single 2x frequency input clock, capable of operating in a range of 40%-60% duty cycle. Onchip, the clock generator unit is responsible for managing the interaction of the CPU core, caches, and bus interface. The clock generator unit replaces the external delay line required in R3000A based applications. Instruction Cache The R3041 integrates 2kB of on-chip Instruction Cache, organized with a line size of 16 bytes (four 32-bit entries) a nd is direct mapped. This relatively large cache substantially contributes to the performance inherent in the R3041, and allows systems based on the R3041 to achieve high-performance even from low-cost memory systems. The cache is implemented as a direct mapped cache, and is capable of caching instructions from anywhere within the 4GB physical address space. The cache is implemented using physical addresses and physical tags (rather than virtual addresses or tags), and thus does not require flushing on context switch. Data Cache The R3041 incorporates an on-chip data cache of 512B, organized as a line size of 4 bytes (one word) and is direct mapped. This relatively large data cache contributes substantially to the performance inherent in the RISController family. As with the instruction cache, the data cache is implemented as a direct mapped physical address cache. The cache is capable of mapping any word within the 4GB physical address space. The data cache is implemented as a write through cache, to insure that main memory is always consistent with the internal cache. In order to minimize processor stalls due to data write operations, the bus interface unit incorporates a 4deep write buffer which captures address and data at the processor execution rate, allowing it to be retired to main memory at a much slower rate without impacting system performance. Bus Interface Unit The RISController family uses its large internal caches to provide the majority of the bandwidth requirements of the execution engine, and thus can utilize a simple bus interface connected to slow memory devices. The RISController family bus interface utilizes a 32-bit address and data bus multiplexed onto a single set of pins. The bus interface unit also provides an ALE (Address Latch Enable) output signal to de-multiplex the A/D bus, and simple handshake signals to process CPU read and write requests. In addition to the read and write interface, the R3041 incorporates a DMA arbiter, to allow an external master to control the external bus. The R3041 augments the basic RISController bus interface capability by adding the ability to directly interface with varying memory port widths, for instructions or data. For example, the R3041 can be used in a system with an 8-bit boot PROM, 16bit font/program cartridges, and 32-bit main memory, transparently to software, and without requiring external data packing, rotation, and unpacking. In addition, the R3041 incorporates the ability to change some of the interface timing of the bus. These features can be used to eliminate external data buffers and take advantage of lower speed and lower cost interface components. One of the bus interface options is the Extended Address Hold mode which adds 1/2 clock of extra address hold time from ALE falling. This allows easier interfacing to FPGAs and ASICs. The R3041 incorporates a 4-deep write buffer to decouple the speed of the execution engine from the speed of the memory system. The write buffers capture and FIFO processor address and data information in store operations, and present it to the bus interface as write transactions at the rate the memory system can accommodate. During main memory writes, the R3041 can break a large datum (e.g. 32-bit word) into a series of smaller transactions (e.g. bytes), according to the width of the memory port being written. This operation is transparent to the software which initiated the store, insuring that the same software can run in true 32-bit memory systems. The RISController family read interface performs both single word reads and quad word reads. Single word reads work with a simple handshake, and quad word reads can either utilize the simple handshake (in lower performance, simple systems) or utilize a tighter timing mode when the memory system can burst data at the processor clock rate. Thus, the system designer can choose to use page or static column mode DRAMs (and possibly use interleaving, if desired, in high-performance systems), or even to use simpler SRAM techniques to reduce complexity. In order to accommodate slower quad word reads, the RISController family incorporates a 4-deep read buffer FIFO, so that the external interface can queue up data within the processor before releasing it to perform a burst fill of the internal caches. In addition, the R3041 can perform on-chip data packing when performing large datum reads (e.g., quad words) from narrower memory systems (e.g., 16-bits). Once again, this operation is transparent to the actual software, simplifying migration of software to higher performance (true 32-bit) systems, and simplifying field upgrades to wider memory. Since this capability works for either instruction or data reads, using 8-, 16-, or 32-bit boot PROMs is easily supported by the 4 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE R3041. SYSTEM USAGE The IDT RISController family is specifically designed to easily connect to low-cost memory systems. Typical low-cost memory systems use inexpensive EPROMs, DRAMs, and application specific peripherals. Figure 4 shows some of the flexibility inherent in the R3041. In this example system, which is typical of a laser printer, a 32bit PROM interface is used due to the size of the PDL interpreter. An embedded system can optionally use an 8-bit boot PROM instead. A 16-bit font/program cartridge interface is provided for add-in cards. A 16-bit DRAM interface is used for a low-cost page frame buffer. In this system example, a field or manufacturing upgrade to a 32-bit page frame buffer is supported by the boot software and DRAM controller. Embedded systems may optionally substitute SRAMs for the DRAMs. Finally various 8/16/32-bit I/O ports such as RS-232/ 422, SCSI, and LAN as well as the laser printer engine interface are supported. Such a system features a very low entry price, with a range of field upgrade options including the ability to upgrade to a more powerful member of the RISController family. ClkIn IDT R3041 RISController Address/ Data R3051 Local Bus Control EPROM and I/O Controller DRAM Controller 32-bit EPROM 16-bit Font Cartridge I/O 16-bit DRAM 16-bit Add-on DRAM 2905 drw 04 Figure 4. Typical R3041-Based Application 5 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE DEVELOPMENT SUPPORT The IDT RISController family is supported by a rich set of development tools, ranging from system simulation tools through PROM monitor and debug support, applications software and utility libraries, logic analysis tools, and sub-system modules. Figure 5 is an overview of the system development process typically used when developing R3041 applications. The RISController family is supported in all phases of project development. These tools allow timely, parallel development of hardware and software for RISController family based applications, and include tools such as: • Optimizing compilers from MIPS Technology, the acknowl- edged leader in optimizing compiler technology. • Cross development tools, available in a variety of development environments. • The high-performance IDT floating point emulation library software. • The IDT Evaluation Board, which includes RAM, EPROM, I/O, and the IDT PROM Monitor. • IDT Laser Printer System boards, which directly drive a lowcost print engine, and runs Adobe PostScript™ Page Description Language • Adobe PostScript Page Description Language running on the IDT RISController family. • The IDT/sim™ PROM Monitor, which implements a full PROM monitor (diagnostics, remote debug support, peek/ System Architecture Evaluation System Development Phase Software DBG Debugger PIXIE Profiler MIPS Compiler Suite Stand-Alone Libraries Floating Point Library Cross Development Tools Adobe PostScript PDL MicroSoft TrueImage PDL PeerlessPage BIOS IDT/kit System Integration and Verfification Cache3041 Benchmarks Evaluation Board Laser Printer System Hardware Hardware Models General CAD Tools RISC Sub-systems '341 Evaluation Board Laser Printer System Logic Analysis Diagnostics IDT/sim PROM Monitor Remote Debug Real-Time OS 2905 drw 05 Figure 5. R3041 Development Environment 6 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE poke, etc.). • IDT/kit™ (Kernel Integration Toolkit), providing library support and a frame work for the system run time environment. vices in their application. PERFORMANCE OVERVIEW The RISController family achieves a very high-level of performance. This performance is based on: • An efficient execution engine: The CPU performs ALU operations and store operations in a single cycle, and has an effective load time of 1.3 cycles, and branch execution rate of 1.5 cycles (based on the ability of the compilers to avoid software interlocks). Thus, the R3041 achieves 20 MIPS performance at 25MHz when operating out of cache. • Large on-chip caches: The RISController family contains caches which are substantially larger than those on the majority of embedded microprocessors. These large caches minimize the number of bus transactions required, and allow the RISController family to achieve actual sustained performance very close to its peak execution rate, even with low-cost memory systems. • Autonomous multiply and divide operations: The RISController family features an on-chip integer multiplier/ divide unit which is separate from the other ALU. This allows the R3041 to perform multiply or divide operations in parallel with other integer operations, using a single multiply or divide instruction rather than using “step” operations. • Integrated write buffer: The R3041 features a four deep write buffer, which captures store target addresses and data at the processor execution rate and retires it to main memory at the slower main memory access rate. Use of onchip write buffers eliminates the need for the processor to stall when performing store operations. • Burst read support: The R3041 enables the system designer to utilize page mode, static column, or nibble mode RAMs when performing read operations to minimize the main memory read penalty and increase the effective cache hit rates. The performance differences among the various RISController family members depends on the application software and the design of the memory system. Different family members feature different cache sizes, and the R3081 features a hardware floating point accelerator. Since all these devices can be used in a pin and software compatible fashion, the system designer has maximum freedom in trading between performance and cost. The memory simulation tools (e.g. Cache3041) allows the system designers to analyze and understand the performance differences among these de- SELECTABLE FEATURES The RISController family uses two methods to allow the system designer to configure bus interface operation options. The first set of options are established via the Reset Configuration Mode inputs, sampled during the device reset. After reset, the Reset Mode inputs become regular input or output signals. The second set of configuration options are contained in the System Control Co-Processor registers. These Co-processor registers configuration options are typically initialized with the boot PROM and can also be changed dynamically by the kernel software. Selectable features include: • Big Endian vs. Little Endian operation: The part can be configured to operate with either byte ordering convention, and in fact may also be dynamically switched between the two conventions. This facilitates the porting of applications from other processor architectures, and also permits intercommunication between various types of processors and databases. • Data Cache Refill of one or four words: The memory system must be capable of performing 4 word transfers to satisfy instruction cache misses and 1 word transfers to satisfy uncached references. The data cache refill size option allows the system designers to choose between one and four word refill on data cache misses, depending on the performance each option brings to their application. • Bus Turn Around speed: The R3041 allows the kernel to increase the amount of time between bus transactions when changes in direction of the A/D bus occur (e.g., at the end of reads followed by writes). This allows transceivers and buffers to be eliminated from the system. • Extended Address Hold Time: The R3041 allows the system designer to increase the amount of hold time available for address latching, thus allowing slower speed (low cost) address latches, FPGAs and ASICs to be used. • Programmable control signals: The R3041 allows the system designer to optimally configure various memory control signals to be active on reads only, writes only, or on both reads and writes. This allows the simplification of external logic, thus reducing system cost. 7 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE • Programmable memory Port Widths: The R3041 allows the kernel to partition the physical memory space into various sub-regions, and to individually indicate the port width of these sub-regions. Thus, the bus interface unit can perform data packing and unpacking when communicating with narrow memory sub-regions. For example, these features, can be used to allow the R3041 to interface with narrow 8-bit boot PROMs, or to implement 16-bit only memory systems. THERMAL CONSIDERATIONS The RISController family utilizes special packaging techniques to improve the thermal properties of high-speed processors. Thus, all versions of the RISController family are packaged in cavity down packaging. The lowest cost members of the family use a standard cavity down, injection molded PLCC package (the “J” package). This package is used for all speeds of the R3041 family. Higher speed and higher performance members of the RISController family utilize more advanced packaging techniques to dissipate power while remaining both low-cost and pin- and socket- compatible with the PLCC package. Thus, these members of the RISController family are available in the MQUAD package (the “MJ” package), which is an all aluminum package with the die attached to a normal copper leadframe mounted to the aluminum casing. The MQUAD package is pin and form compatible with the PLCC package. Thus, designers can choose to utilize this package without changing their PCB. The members of the RISController family are guaranteed in a case temperature range of 0°C to +85°C. The type of package, speed (power) of the device, and airflow conditions, affect the equivalent ambient conditions which meet this specification. The equivalent allowable ambient temperature, TA, can be calculated using the thermal resistance from case to ambient (ØCA) of the given package. The following equation relates ambient and case temperature: TA = TC - P * ØCA where P is the maximum power consumption at hot temperature, calculated by using the maximum Icc specification for the device. Typical values for ØCA at various airflows are shown in Table 2 for the PLCC package. NOTES ON SYSTEM DESIGN The R3041 has been designed to simplify the task of highspeed system design. Thus, set-up and hold-time requirements have been kept to a minimum, allowing a wide variety of system interface strategies. To minimize these AC parameters, the R3041 employs feedback from its SysClk output to the internal bus interface unit. This allows the R3041 to reference input signals to the reference clock seen by the external system. The SysClk output is designed to provide relatively large AC drive to minimize skew due to slow rise or fall times. A typical part will have less than 2ns rise or fall (10% to 90% signal times) when driving the test load. Therefore, the system designer should use care when designing for direct SysClk use. Total loading (due to devices connected on the signal net and the routing of the net itself) should be minimized to ensure the SysClk output has a smooth and rapid transition. Long rise and/or fall times may cause a degradation in the speed capability of an individual device. Similarly, the R3041 employs feedback on its ALE output to ensure adequate address hold time to ALE. The system designer should be careful when designing the ALE net to minimize total loading and to minimize skew between ALE and the A/D bus, which will ensure adequate address access latch time. IDT's field and factory applications groups can provide the system designer with assistance for these and other design issues. Airflow (ft/min) ØCA "J" Package TQFP 0 29 55 200 26 40 400 21 35 600 18 33 800 16 31 1000 15 30 2905 tbl 02 Table 2. Thermal Resistance (ØCA) at Various Airflows 8 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE PIN CONFIGURATIONS A/D(31) A/D(30) A/D(29) A/D(28) A/D(27) A/D(26) A/D(25) A/D(24) A/D(23) A/D(22) A/D(21) A/D(20) A/D(19) A/D(18) A/D(17) A/D(16) VSS VCC ClkIn 11 10 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 9 8 7 6 5 4 3 2 1 84 83 82 81 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 A/D(15) VCC VSS VCC VSS VSS VCC A/D(14) A/D(13) A/D(12) A/D(11) A/D(10) A/D(9) VCC VSS A/D(8) A/D(7) A/D(6) A/D(5) A/D(4) A/D(3) VSS VCC A/D(2) A/D(1) A/D(0) TriState BE16(1) BE16(0) Addr(1) Addr(0) Int(5) VSS VCC IDT R3041/RV3041 65 64 63 62 61 60 59 58 57 56 55 54 53 Int(4) Int(3) SInt(2) SInt(1) SInt(0) SBrCond(3)/ IOStrobe SBrCond(2)/ ExtDataEn TC VSS VCC 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 MemStrobe BusReq RdCEn Ack BusError Reset BusGnt SysClk Diag VSS Burst/WrNear 2905 drw 06 Addr(2) 84-Pin PLCC/ Top View (Cavity Down) Addr(3) VCC DataEn Wr Rd ALE Last VCC VSS 9 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE PIN CONFIGURATIONS NC NC A/D(31) A/D(30) A/D(29) A/D(28) A/D(27) VSS VCC A/D(26) A/D(25) A/D(24) A/D(23) A/D(22) A/D(21) VCC VSS A/D(20) A/D(19) A/D(18) A/D(17) A/D(16) A/D(15) NC NC NC NC VSS VCC A/D(14) A/D(13) A/D(12) A/D(11) A/D(10) A/D(9) VCC VSS A/D(8) A/D(7) A/D(6) A/D(5) A/D(4) A/D(3) VSS VCC A/D(2) A/D(1) A/D(0) NC NC 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 100 26 99 27 98 28 97 29 96 30 95 31 94 32 93 33 92 34 91 35 90 36 89 37 IDT R3041/RV3041 38 88 100-Pin 39 87 TQFP (Cavity Up) 40 86 Top View 41 85 42 84 43 83 44 82 45 81 46 80 47 79 48 78 49 77 50 76 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 NC NC NC NC NC NC VSS VCC ClkIn TriState BE16(1) BE16(0) Addr(1) Addr(0) Int(5) VSS VCC Int(4) Int(3) SInt(2) SInt(1) SInt(0) TC SBrCond(3)/IOStrobe SBrCond(2)/ExtDataEn VSS VCC NC NC MemStrobe BusReq RdCEn Ack BusError Reset BusGnt SysClk DataEn Wr Rd VSS VCC Burst/WrNear Diag VSS VCC Addr(2) Addr(3) Last ALE 2905 drw 06 10 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE PIN DESCRIPTION PIN NAME A/D(31:0) I/O I/O DESCRIPTION Address/Data: A 32-bit time multiplexed bus which indicates the desired address for a bus transaction in one phase, and which is used to transmit data between the CPU and external memory resources during the rest of the transfer. Bus transactions on this bus are logically separated into two phases: during the first phase, information about the transfer is presented to the memory system to be captured using the ALE output. This information consists of: Address(31:4): The high-order address for the transfer is presented on A/D(31:4). These strobes indicate which bytes of the 32-bit bus will be involved in the transfer, and are presented on A/D(3:0). BE(3) indicates that A/D(31:24) will be used, and BE(0) corresponds to A/D(7:0). These strobes are only valid for accesses to 32-bit wide memory ports. Note that BE(3:0) can be held in-active during reads by setting the appropriate bit of CP0; thus when latched, these signals can be directly used as Write Enable strobes. BE(3:0): During the second phase, these signals are the data bus for the transaction. Data(31:0): During write cycles, the bus contains the data to be stored and is driven from the internal write buffer. On read cycles, the bus receives the data from the external resource, in either a single data transaction or in a burst of four words, and places it into the on-chip read buffer. The byte lanes used during the transfer are a function of the datum size, the memory port width, and the system byte-ordering. Addr(3:0) O Low Address (3:0) A 4-bit bus which indicates which word/halfword/byte is currently expected by the processor. For 32-bit port widths, only Addr(3:2) is valid during the transfer; for 16-bit port widths, only Addr(3:1) are valid; for 8-bit port widths, all of Addr(3:0) are valid. These address lines always contain the address of the current datum to be transferred. In writes and single datum reads, the addresses initially output the specific target address, and will increment if the size of the datum is wider than the target memory port. For quad word reads, these outputs function as a counter starting at '0000', and incrementing according to the width of the memory port. During Reset, the Addr(3:0) pins act as Reset Configuration Mode bit inputs for the BootProm16, BootProm8, ReservedHigh, and ExtAddrHold options. The R3041 Addr(1:0) output pins are designated as the unconnected Rsvd(1:0) pins in the R3051 and R3081. Diag O Diagnostic Pin. This output indicates whether the current bus read transaction is due to an onchip cache miss and whether the read is an instruction or data. It is time multiplexed as described below: Cached/Uncached: During the phase in which the A/D bus presents address information, this pin is an active high output which indicates whether or not the current read is a result of a cache miss. The value of this pin at this time other than in read cycles is undefined. A high at this time indicates an instruction reference, and a low indicates a data reference. The value of this pin at this time other than in read cycles is undefined. I(1) I/D: The R3041 Diag output pin is designated as the Diag(1) output pin in the R3051 and R3081. ALE O Address Latch Enable: Used to indicate that the A/D bus contains valid address information for the bus transaction. This signal is used by external logic to capture the address for the transfer, typically by using transparent latches. O Data Enable: This signal indicates that the A/D bus is no longer being driven by the processor during read cycles, and thus the external memory system may enable the drivers of the memory system onto this bus without having a bus conflict occur. During write cycles, or when no bus transaction is occurring, this signal is negated, thus disabling the external memory drivers. NOTE: 1. Reset Configuration Mode bit input when Reset is asserted, normal signal function when Reset is de-asserted. 2905 tbl 03 DataEn 11 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE PIN DESCRIPTION (Continued): PIN NAME I/O O DESCRIPTION Burst Transfer/Write Near: On read transactions, the Burst signal indicates that the current bus read is requesting a block of four contiguous words from memory. This signal is asserted only in read cycles due to cache misses; it is asserted for all I-Cache miss read cycles, and for D-Cache miss read cycles if the 4-word data block refill option is selected in the CP0 Cache Config Register. On write transactions, the WrNear output tells the external memory system that the bus interface unit is performing back-to-back write transactions to an address within the same 256 byte page as the prior write transaction. This signal is useful in memory systems which employ page mode or static column DRAMs, and allows nearby writes to be retired quickly. Burst/ WrNear Rd Wr Ack O O I Read: An output which indicates that the current bus transaction is a read. Write: An output which indicates that the current bus transaction is a write. Acknowledge: An input which indicates to the device that the memory system has sufficiently processed the bus transaction. On write transactions, this signal indicates that the CPU may either progress to the next data item (for mini-burst writes of wide datums to narrow memories), or terminate the write cycle. On read transactions, this signal indicates that the memory system has sufficiently processed the read, and that the processor core may begin processing the data from this read transfer. Read Buffer Clock Enable: An input which indicates to the device that the memory system has placed valid data on the A/D bus, and that the processor may move the data into the on-chip Read Buffer. System Reference Clock: An output from the CPU which reflects the timing of the internal processor "System" clock. This clock is used to control state transitions in the read buffer, write buffer, memory controller, and bus interface unit. DMA Arbiter Bus Request: An input to the device which requests that the CPU tri-state its bus interface signals so that they may be driven by an external master. The negation of this input relinquishes mastership back to the CPU. DMA Arbiter Bus Grant. An output from the CPU used to acknowledge that a BusReq has been detected, and that the bus is relinquished to the external master. The R3041 adds an additional DMA protocol, under the control of CP0. If the DMA Protocol is enabled, the R3041 can request that the external master relinquish bus mastership back to the processor by negating the BusGnt output early, and waiting for the BusReq input to be negated. RdCEn SysClk BusReq BusGnt I O I O SBrCond(3)/ IOStrobe I/O Branch Condition Port/IO Strobe: The use of this signal depends on the setting of various bits of the CP0 Bus Control register. If BrCond mode is selected, this input is logically connected to CpCond(3), and can be used by the branch on co-processor condition instructions as an input port. The SBrCond(3) input has special internal logic to synchronize the input, and thus may be driven by asynchronous agents. If this pin is selected to function as IOStrobe, it may be asserted as an output on reads, writes, or both, as programmed into CP0. This strobe asserts in the second clock cycle of a transfer, and thus can be used to strobe various control signals on the bus interface. SBrCond(2)/ ExtDataEn I/O Branch Condition Port/Extended Data Enable: The use of this signal depends on the settings in the CP0 Bus Control register. If BrCond mode is selected, this input is logically connected to CpCond(2), and can be used by the branch on co-processor condition instructions as an input port. The SBrCond(2) input has special internal logic to synchronize the input, and thus may be driven by asynchronous agents. If this pin is selected to function as Extended Data Enable, it may be asserted as an output on reads, writes, or both, as programmed into CP0. This strobe can be used as an extended data enable strobe, in that it is held asserted for one-half clock cycle after the negation of Rd or Wr. This signal may typically be used as a write enable control line for transceivers, as a write line for I/O, or as an address mux select for DRAMs. MemStrobe O Memory Strobe: This active low output pulses low for each data read or written, as configured in the CP0 Bus Control register. Thus, it can be used as a read strobe, write strobe, or both, for SRAM type memories or for I/O devices. The R3041 MemStrobe output pin is designated as the BrCond(0) input pin in the R3051 and R3081. 2905 tbl 04 12 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE PIN DESCRIPTION (Continued): PIN NAME I/O O DESCRIPTION Byte Enable Strobes for 16-bit Memory Port: These active low outputs are the byte lane strobes for accesses to 16-bit wide memory ports; they are not necessarily valid for 8- or 32-bit wide ports. If BE16(1) is asserted, then the most significant byte (either D(31:24) or D(15:8), depending on system endianness) is going to be used in this transfer. If BE16(0) is asserted, the least significant byte (D(23:16) or D(7:0)) will be used. BE16(1:0) BE16(1:0) can be held inactive (masked) during read transfers, according to the programming of the CP0 Bus Control register. I (1) During Reset, the BE16(1:0) act as Reset Configuration Mode bit inputs for two ReservedHigh options. The BE16(1:0) output pins are designated as the unconnected Rsvd(3:2) pins in the R3051 and R3081. Last O Last Datum in Mini-Burst: This active low output indicates that this is the last datum transfer in a given transaction. It is asserted after the next to last RdCEn (reads) or Ack (writes), and is negated when Rd or Wr is negated. The Last output pin is designated in the R3051 and R3081 as the Diag(0) output pin. TC O Terminal Count: This is an active low output from the processor which indicates that the on-chip timer has reached its terminal count. It will remain low for either 1.5 clock cycles, or until software resets the timer, depending on the mode selected in the CP0 Bus Control register. Thus, the on-chip timer can function either as a free running timer for system functions such as DRAM refresh, or can operate as a software controlled time-slice timer, or real-time clock. The TC output pin is designated in the R3051 as the BrCond(1) input pin, and in the R3081 as the Run pin output. BusError Int(5:3) SInt(2:0) I Bus Error: Input to the bus interface unit to terminate a bus transaction due to an external bus error. This signal is only sampled during read and write operations. If the bus transaction is a read operation, then the CPU will take a bus error exception. Processor Interrupt: During normal operation, these signals are logically the same as the Int(5:0) signals of the R3000A. During processor reset, these signals perform mode initialization of the CPU, but in a different (simpler) fashion than the interrupt signals on the original R3000A. During Reset, Int(3) and SInt(0) act as Reset Configuration Mode bit inputs for the AddrDisplayAndForceCacheMiss and BigEndian options. There are two types of interrupt inputs: the SInt inputs are internally synchronized by the processor, and may be driven by an asynchronous external agent. The direct interrupt inputs are not internally synchronized, and thus must be externally synchronized to the CPU. The direct interrupt inputs have one cycle lower latency than the synchronized interrupts. I I(1) ClkIn I I I Master Clock Input: This is a double frequency input used to control the timing of the CPU. Master Processor Reset: This signal initializes the CPU. Reset initialization mode selection is performed during the last cycle of Reset. Tri-State: This input to the R3041 requests that the R3041 tri-state all of its outputs. In addition to those outputs tri-stated during DMA, tri-state will cause SysClk, TC, and BusGnt to tri-state. This signal is intended for use during board testing and emulation during debug and board manufacture. The TriState input pin is designated as the unconnected Rsvd(4)pin in the R3051 and R3081. Reset TriState Vcc Vss I I Power: These inputs must be supplied with the rated supply voltage (VCC). All Vcc inputs must be connected to insure proper operation. Ground: These inputs must be connected to ground (GND). All Vss inputs must be connected to insure proper operation. 2905 tbl 05 NOTE: 1. Reset Configuration Mode bit input when Reset is asserted, normal signal function when Reset is de-asserted. 13 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE ABSOLUTE MAXIMUM RATINGS(1, 3) R3041 Symbol VTERM TC TBIAS TSTG VIN Rating Terminal Voltage with Respect to GND Operating Case Temperature Temperature Under Bias Storage Temperature Input Voltage Commercial –0.5 to +7.0 0 to +85 –55 to +125 –55 to +125 –0.5 to +7.0 Unit V °C °C °C V RECOMMENDED OPERATING TEMPERATURE AND SUPPLY VOLTAGE Grade Commercial Temperature 0°C to +85°C (Case) GND 0V VCC 5.0 ±5% 2905 tbl 07 NOTES: 2905 tbl 06 1. Stresses greater than those listed under ABSOLUTE MAXIMUM RATINGS may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect reliability. 2. VIN minimum = –3.0V for pulse width less than 15ns. VIN should not exceed VCC +0.5 Volts. 3. Not more than one output should be shorted at a time. Duration of the short should not exceed 30 seconds. OUTPUT LOADING FOR AC TESTING +4mA V REF +1.5V + CLD To Device Under Test AC TEST CONDITIONS R3041 Symbol VIH VIL VIHS VILS Parameter Input HIGH Voltage Input LOW Voltage Input HIGH Voltage Input LOW Voltage Min. 3.0 — 3.5 — Max. — 0 — 0 Unit V V V V 2905 tbl 08 -4mA 2905 drw 07 Signal All Signals Cld 25 pF 2905 tbl 09 DC ELECTRICAL CHARACTERISTICS R3041 — (TC = 0°C to +85°C, VCC = +5.0V ±5%) 16.67MHz Symbol VOH VOL VIH VIL VIHS VILS CIN COUT ICC IIH IIL IOZ Parameter Output HIGH Voltage Output LOW Voltage Input HIGH Input LOW Input HIGH Input LOW Input Voltage(3) Voltage(1) Voltage(2,3) Voltage(1,2) Test Conditions VCC = Min., IOH = –4mA VCC = Min., IOL = 4mA — — — — — — VCC = 5V, TC = 25°C VIH = VCC VIL = GND VOH = 2.4V, VOL = 0.5V Min. 3.5 — 2.0 — 3.0 — — — — — –100 –100 Max. — 0.4 — 0.8 — 0.4 10 10 225 100 — 100 20MHz Min. 3.5 — 2.0 — 3.0 — — — — — –100 –100 Max. — 0.4 — 0.8 — 0.4 10 10 250 100 — 100 25MHz Min. 3.5 — 2.0 — 3.0 — — — — — –100 –100 Max. — 0.4 — 0.8 — 0.4 10 10 300 100 — 100 33MHz Min. 3.5 — Max. Unit — V V V V V V pF pF mA µA µA µA 2.0 — 3.0 — — — — — Capacitance(4) Capacitance(4) Output Operating Current Input HIGH Leakage Input LOW Leakage Output Tri-state Leakage –100 –100 NOTES: 1. VIL Min. = –3.0V for pulse width less than 15ns. VIL should not fall below –0.5 volts for larger periods. 2. VIHS and VILS apply to CIkIn and Reset. 3. VIH should not be held above VCC + 0.5 volts. 4. Guaranteed by design. ADVANCED 0.4 — 0.8 — 0.4 10 10 370 100 — 100 2905 tbl 10 14 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE AC ELECTRICAL CHARACTERISTICS R3041 Symbol t1 t1a t2 t2a t3 t4 t5 t6 t7 t7a t7b t8 t9 t10 t11 t12 t14 t15 t16 t17 t18 t19 t20 t21 t22 t23 t24 t25 t26 t27 t28 t29 t30 t31 tsys t32 t33 Signals Description Set-up to SysClk rising Set-up to SysClk falling Hold from SysClk rising Hold from SysClk falling Tri-state from SysClk rising (after driven condition) Driven from SysClk falling (after tri-state condition) (1, 2, 3) — (TC = 0°C to +85°C, VCC = +5.0V ±5%) 16.67MHz 20MHz Min. 8 9 3 2 — — — — — — — — — 2 — 0 0 — — — — — 10 10 25 200 32 6 6 2.5 6 3 6 3 2*t22 Max. — — — — 10 10 8 8 6 9 9 4 4 — 15 — — 7 8 12 10 13 — — 250 — — — — — — — — — 2*t22 25MHz Min. 5.5 7 2.5 1 — — — — — — — — — 2 — 0 0 — — — — — 8 8 20 200 32 5 5 2.5 5 3 5 3 2*t22 Max. — — — — 10 10 7 7 5 8 8 4 4 — 15 — — 6 7 11 10 12 — — 250 — — — — — — — — — 2*t22 33MHz BusReq, Ack, BusError, RdCEn A/D 11 12 4 2 — — — — — — — — — 2 — 0 0 — — — — — 12 12 30 200 32 8 8 2.5 8 4 8 4 2*t22 — — — — 13 13 10 10 8 12 12 5 5 — 19 — — 9 11 15 13 16 — — 250 — — — — — — — — — 2*t22 5.5 7 ADV ANCED — — — 10 10 7 7 5 8 8 4 4 15 — — 6 7 11 10 — 12 — 250 — — — — — — — — — 2*t22 Min. Max. Min. Max. Unit ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns µs sys ns ns ns ns ns ns ns ns ns ns BusReq, Ack, BusError, RdCEn A/D A/D, Addr, Diag, ALE, Wr Burst/WrNear, Rd, DataEn A/D, Addr, Diag, ALE, Wr Burst/WrNear, Rd, DataEn BusGnt BusGnt Wr, Rd, Burst/WrNear, TC A/D 2.5 1 — — Asserted from SysClk rising Valid from SysClk rising Valid from SysClk rising Valid from SysClk rising Asserted from SysClk rising — — — — — — Negated from SysClk falling Last ALE ALE A/D — Negated from SysClk falling Hold from ALE negated Asserted from SysClk Asserted from A/D tri-state(4) Negated from SysClk falling Valid from SysClk Driven from SysClk rising(4) 1.5 — 0 0 DataEn DataEn A/D Wr, Rd, DataEn, Burst/WrNear, Last, TC Addr(3:0), BE 16(1:0) Diag A/D A/D ClkIn ClkIn ClkIn — — Tri-state from SysClk SysClk to data out Pulse Width High Pulse Width Low Clock Period Pulse Width from Vcc valid Minimum Pulse Width Set-up to SysClk falling Mode set-up to Reset rising Set-up to SysClk falling Set-up to SysClk falling Pulse Width Clock High Time Clock Low Time Valid from SysClk — — — 6.5 6.5 15 32 5 5 5 3 5 3 Reset Reset Reset Int Int SInt, SBrCond SInt, SBrCond Int, BrCond Int, BrCond SysClk SysClk SysClk 200 Mode hold from Reset rising 2.5 Hold from SysClk falling Hold from SysClk falling 2*t22 t22 - 2 t22 + 2 t22 - 2 t22 + 2 t22 - 2 t22 + 2 t22 - 2 t22 + 2 t22 - 2 t22 + 2 t22 - 2 t22 + 2 t22 - 2 t22 + 2 t22 - 2 t22 + 2 2905 tbl 11 15 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE AC ELECTRICAL CHARACTERISTICS R3041 (CONT.) 16.67MHz Symbol t45 t46 t47 t48 t49 t50 t51 t52 tderate 20MHz Min. — — — — — — — 0 — Max. 10 10 8 12 7 15 15 — 0.5 25MHz Min. — — — — — — — 0 — Max. 10 10 7 9 6 15 15 — 0.5 33MHz ExtDataEn ExtDataEn Driven from SysClk falling (after driven condition) Valid from SysClk falling Asserted from SysClk rising Negated from SysClk rising Asserted from SysClk rising — — — — — — 0 — 13 10 15 9 19 19 — 0.5 — ADVANCED 10 7 9 6 15 — 15 0.5 Signals Description Tri-state from SysClk rising (after driven condition) Min. — Max. 13 Min. — Max. 10 Unit ns ns ns ns ns ns ns ns ns/ 25pF IOStrobe ExtDataEn, DataEn ExtDataEn MemStrobe MemStrobe MemStrobe All outputs — — — 0 — — Negated from SysClk falling Asserted from Addr(3:0) valid(4) Timing deration for loading over 25pF(4, 5) — NOTES: 2905 tbl 12 1. All timings referenced to 1.5 Volts, with a rise and fall time of less than 2.5ns. 2. All outputs tested with 25pF loading. 3. The AC values listed here reference timing diagrams contained in the R3041 Hardware User's Manual. 4. Guaranteed by design. 5. This parameter is used to derate the AC timings according to the loading of the system. This parameter provides a deration for loads over the specified test condition; that is, the deration factor is applied for each 25pF over the specified test load condition. 6. Timings t34 - t44 are reserved for other RISController family members. ABSOLUTE MAXIMUM RATINGS(1, 3) RV3041 Symbol VTERM TC TBIAS TSTG VIN Rating Terminal Voltage with Respect to GND Operating Case Temperature Temperature Under Bias Storage Temperature Input Voltage Commercial –0.5 to +7.0 0 to +85 –55 to +125 –55 to +125 –0.5 to +7.0 Unit V °C °C °C V RECOMMENDED OPERATING TEMPERATURE AND SUPPLY VOLTAGE Grade Commercial RV3041 Temperature 0°C to +85°C (Case) GND 0V VCC 3.3 ±5% 2905 tbl 07 NOTES: 2905 tbl 06 1. Stresses greater than those listed under ABSOLUTE MAXIMUM RATINGS may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect reliability. 2. VIN minimum = –3.0V for pulse width less than 15ns. VIN should not exceed VCC +0.5 Volts. 3. Not more than one output should be shorted at a time. Duration of the short should not exceed 30 seconds. OUTPUT LOADING FOR AC TESTING +4mA V REF +1.5V + CLD To Device Under Test AC TEST CONDITIONS RV3041 Symbol VIH VIL VIHS VILS Parameter Input HIGH Voltage Input LOW Voltage Input HIGH Voltage Input LOW Voltage Min. 3.0 — 3.0 — Max. — 0 — 0 Unit V V V V 2905 tbl 08 -4mA 2905 drw 07 Signal All Signals Cld 25 pF 2905 tbl 09 16 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE DC ELECTRICAL CHARACTERISTICS RV3041 — (TC = 0°C to +85°C, VCC = +3.3V ±5%) 16.67MHz Symbol VOH VOL VIH VIL VIHS VILS CIN COUT ICC IIH IIL IOZ Parameter Output HIGH Voltage Output LOW Voltage Input HIGH Voltage(3) Input LOW Voltage(1) Input HIGH Voltage(2,3) Input LOW Voltage(1,2) Input Capacitance(4) Output Capacitance(4) Operating Current Input HIGH Leakage Input LOW Leakage Output Tri-state Leakage Test Conditions VCC = Min., IOH = –4mA VCC = Min., IOL = 4mA — — — — — — VCC = 3.3V, TC = 25°C VIH = VCC VIL = GND VOH = 2.4V, VOL = 0.5V Min. 2.4 — 2.0 — 2.5 — — — — — –100 –100 Max. — 0.4 — 0.8 — 0.4 10 10 130 100 — 100 20MHz Min. 2.4 — 2.0 — 2.5 — — — — — –100 –100 Max. — 0.4 — 0.8 — 0.4 10 10 150 100 — 100 25MHz Min. 2.4 — 2.0 — 2.5 — — — — — –100 –100 Max. — 0.4 — 0.8 — 0.4 10 10 180 100 — 100 33MHz Min. 2.4 — Max. Unit — V V V V V V pF pF mA mA mA mA 2905 tbl 10 2.0 — 2.5 — –100 –100 NOTES: 1. VIL Min. = –3.0V for pulse width less than 15ns. VIL should not fall below –0.5 volts for larger periods. 2. VIHS and VILS apply to CIkIn and Reset. 3. VIH should not be held above VCC + 0.5 volts. 4. Guaranteed by design. AC ELECTRICAL CHARACTERISTICS RV3041 Symbol t1 t1a t2 t2a t3 t4 t5 t6 t7 t7a t7b t8 t9 t10 t11 t12 t14 t15 t16 t17 Signals BusReq, Ack, BusError, Description Set-up to SysClk rising Set-up to SysClk falling Hold from SysClk rising (1, 2, 3) — (TC = 0°C to +85°C, VCC = +3.3V ±5%) 16.67MHz 20MHz 25MHz 33MHz Min. Max. Min. Max. Min. Max. Min. Max. Unit 11 — 8 — 5.5 — 5.5 — ns 12 4 2 — — — — — — — — — 2 — 0 0 — — — — — — 13 13 10 10 8 12 12 5 5 — 19 — — 9 11 15 9 3 2 — — — — — — — — — 2 — 0 0 — — — — — — 10 10 8 8 6 9 9 4 4 — 15 — — 7 8 12 7 2.5 1 — — — — — — — — — 2 — 0 0 — — — — — — 10 10 7 7 5 8 8 4 4 — 15 — — 6 7 11 7 2.5 1 — RdCEn A/D ADVANCED — — — 10 10 7 7 5 8 8 4 4 15 — — 6 7 11 ADVANCED 0.4 — 0.8 — 0.4 10 10 — — — 225 — 100 — 100 — — — — — — — — 1.5 — 0 0 — — — BusReq, Ack, BusError, RdCEn A/D A/D, Addr, Diag, ALE, Wr Burst/WrNear, Rd, DataEn A/D, Addr, Diag, ALE, Wr Burst/WrNear, Rd, DataEn ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns BusGnt BusGnt Wr, Rd, Burst/WrNear, TC A/D Last ALE ALE A/D DataEn DataEn Wr, Rd, DataEn, Burst/WrNear, Last, TC Addr(3:0), BE 16(1:0) Diag A/D Hold from SysClk falling Tri-state from SysClk rising (after driven condition) Driven from SysClk falling (after tri-state condition) Asserted from SysClk rising Negated from SysClk falling Valid from SysClk rising Valid from SysClk rising Valid from SysClk rising Asserted from SysClk rising Negated from SysClk falling Hold from ALE negated Asserted from SysClk Asserted from A/D tri-state(4) Driven from SysClk rising(4) Negated from SysClk falling Valid from SysClk Valid from SysClk 2905 tbl 11 17 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE AC ELECTRICAL CHARACTERISTICS RV3041 (CONT.) 16.67 MHz Symbol t18 t19 t20 t21 t22 t23 t24 t25 t26 t27 t28 t29 t30 t31 tsys t32 t33 t45 t46 t47 t48 t49 t50 t51 t52 tderate A/D A/D ClkIn ClkIn ClkIn Signals Description Min. — — 12 12 30 200 32 8 8 2.5 8 4 8 4 2*t22 t22 - 2 t22 - 2 — — — — — — — 0 — Max. 13 16 — — 250 — — — — — — — — — 2*t22 t22 + 2 t22 + 2 13 13 10 15 9 19 19 — 0.5 Tri-state from SysClk 20 MHz Min. — — 10 10 25 200 32 6 6 2.5 6 3 6 3 2*t22 Max. 10 13 — — 250 — — — — — — — — — 25MHz Min. — — 8 8 20 200 32 5 5 2.5 5 3 5 3 Max. 10 12 — — 250 — — — — — — — — — 2*t22 33MHz Min. — — Max. 10 — 12 — Unit ns ns ns ns ns µs sys ns ns ns ns ns ns ns ns SysClk to data out Pulse Width High Pulse Width Low Clock Period 6.5 6.5 15 32 5 5 Reset Reset Reset Int Int SInt, SBrCond SInt, SBrCond Int, BrCond Int, BrCond SysClk SysClk SysClk ExtDataEn ExtDataEn IOStrobe ExtDataEn, ExtDataEn DataEn MemStrobe MemStrobe MemStrobe All outputs Pulse Width from Vcc valid Minimum Pulse Width Set-up to SysClk falling Mode set-up to Reset rising Set-up to SysClk falling 200 Mode hold from Reset rising Hold from SysClk falling 2.5 5 3 5 3 Set-up to SysClk falling Pulse Width Clock High Time Clock Low Time Hold from SysClk falling 2*t22 2*t22 2*t22 2*t22 t22 - 2 t22 + 2 t22 - 2 t22 + 2 t22 - 2 t22 + 2 ns t22 - 2 t22 + 2 t22 - 2 t22 + 2 t22 - 2 t22 + 2 ns — — — — — — — 0 — 10 10 8 12 7 15 15 — 0.5 — — — — — — — 0 — 10 10 7 9 6 15 15 — 0.5 — 10 ns ns ns ns ns ns ns ns ns/ 25pF Tri-state from SysClk rising (after driven condition) Driven from SysClk falling (after driven condition) Valid from SysClk falling Asserted from SysClk rising Negated from SysClk rising — — — — Asserted from SysClk rising — 0 Negated from SysClk falling Asserted from Addr(3:0) valid(4) — — Timing deration for loading over 25pF(4, 5) NOTES: 2905 tbl 12 1. All timings referenced to 1.5 Volts, with a rise and fall time of less than 2.5ns. 2. All outputs tested with 25pF loading. 3. The AC values listed here reference timing diagrams contained in the R3041 Hardware User's Manual. 4. Guaranteed by design. 5. This parameter is used to derate the AC timings according to the loading of the system. This parameter provides a deration for loads over the specified test condition; that is, the deration factor is applied for each 25pF over the specified test load condition. 6. Timings t34 - t44 are reserved for other RISController family members. ADVANCED 250 — — — — — — — — — 10 7 9 6 15 — 15 0.5 18 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE t22 ClkIn t20 t21 SysClk t32 t33 tsys Figure 8. RISController Family Clocking 2905 drw 08 VCC ClkIn Reset Figure 9. Power-On Reset Sequence t23 2905 drw 09 ClkIn Reset t24 2905 drw 10 Figure 10(a). Warm Reset Sequence ClkIn Reset t23 2905 drw 11 Figure 10(b). Warm Reset Sequence (Internal Pull-Ups Used) SysClk Reset Mode Vector Inputs: SInt(2:0), Int(5:3) Mode Vector Inputs: Addr(3:0), BE16(1:0) t26 t25 External Device Drives Signals CPU Drives t27 Figure 11. Mode Selection and Negation of Reset t4 2905 drw 12 19 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE Address Memory SysClk t7 Rd t14 A/D(31:0) t16 Addr(3:2) t8 ALE t9 t7a Addr BE Turn Bus Sample Data? t18 t10 t12 DataEn t17 Diag Cached? t11 t17 I/D 2905 drw 13 Figure 12(a). Start of Read Timing with Non-Extended Address Hold Option Address Memory SysClk t7 Rd t14 A/D(31:0) t16 Addr(3:2) t8 ALE t9 t7a Addr BE Extend Address Sample Data? t18 t12 DataEn t17 Diag Cached? t48 t17 I/D 2905 drw 14 Figure 12(b). Start of Read Timing with Extended Address Hold Option 20 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE Address Memory SysClk t7 Wr t7a t14 A/D(31:0) t16 Addr(3:2) t8 ALE t9 Addr BE Data Phase End Write? t19 Data Out t10 t48 ExtDataEn t7 WrNear 2905 drw 15 Figure 12(c). Start of Write Timing with Non-Extended Address Hold Option Address Memory SysClk t7 Wr t7a t14 A/D(31:0) t16 Addr(3:2) t8 ALE t9 Extended Address End Write? t19 Addr BE Data Out t48 ExtDataEn t7 WrNear 2905 drw 16 Figure 12(d). Start of Write Timing with Extended Address Hold Option 21 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE Run/ Stall Stall Stall Stall Stall Stall Fixup PhiClk SysClk t7 Rd t14 A/D(31:0) t16 Addr(3:2) t8 ALE t12 DataEn t49 ExtDataEn t7 Burst t7b Last t18 t12 MemStrobe t50 IOStrobe t15 t47 t51 t15 t48 t15 t9 Word Address t15 t7a Addr BE t18 t1a Data Input t14 t2a t16 t1 RdCEn t2 Ack t17 Diag Cached? t17 I/D t17 Start Extended Ack/ Read Address RdCEn ? Ack/ RdCEn ? Ack/ Sample RdCEn Data End Read 2905 drw 17 Figure 13. Single Datum Read 22 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE Run/ Stall Stall Stall Stall Stall Stall Stall Fixup PhiClk SysClk t7 Rd t14 A/D(31:0) t16 Addr(3:0) t8 ALE t12 DataEn t49 ExtDataEn t7 Burst t7b Last t18 t12 t50 MemStrobe t51 t47 IOStrobe t1 RdCEn t2 Ack t17 Diag Cached? t15 t14 t1a Addr Byte 0 t7a t1a Byte 1 t1a Byte 2 t1a Byte 3 t18 'nn00' t2a 'nn01' t2a 'nn10' t2a 'nn11' t2a t9 t16 t16 t16 t16 t15 t48 t15 t15 t50 t51 t50 t51 t50 t51 t15 t1 t2 t1 t2 t1 t2 t17 I/D t17 Start Extended RdCEn Read Address Sample RdCEn Sample RdCEn Sample Ack/ Sample New Data Data RdCEn Data Transaction Data 2905 drw 18 Figure 14. Mini-burst read of 32-bit datum from 8-bit wide memory port 23 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE Run/ Stall Refill/ Fixup Stall Stall Stall Word 0 Refill/ Stream/ Fixup Word 1 Refill/ Stream/ Fixup Word 2 Refill/ Stream/ Fixup Word 3 PhiClk SysClk t7 Rd t14 A/D(31:0) t16 Addr(3:2) t8 ALE t12 DataEn t49 ExtDataEn t7 Burst t7b Last t18 t12 t50 MemStrobe t51 t47 IOStrobe t1 RdCEn t2 Ack t17 Diag Cached t15 t14 t1a Addr BE Word 0 t7a t1a Word 1 t1a Word 2 t1a Word 3 t18 '00' t2a '01' t2a '10' t2a '11' t2a t9 t16 t16 t16 t16 t15 t48 t15 t50 t51 t50 t51 t50 t51 t15 t1 t2 t1 t2 t1 t2 t17 I/D t17 Start Extended Ack/ Read Address RdCEn Sample RdCEn Sample RdCEn Sample RdCEn Sample New Data Data Data Transaction Data 2905 drw 19 Figure 15. R3041 Quad Word Read 24 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE Run/ Stall Stall Stall Stall Stall Stall Stall Stall PhiClk SysClk t7 Rd t14 A/D(31:0) t16 Addr(3:1) t8 ALE t7a Addr t15 t14 t1a Halfword 0 t1a Halfword 1 t1a Halfword 2 t1a Halfword 3 t18 '000' t2a '001' t2a '010' t2a '011' t2a '100' t9 t16 t16 t16 t16 BE16(1:0) t16 DataEn '00' '00' '00' '00' '00' t12 t16 t16 t16 t16 ExtDataEn t7 Burst t48 Last t18 t12 t50 t51 t50 t47 t50 t51 t50 t51 t50 t51 MemStrobe IOStrobe t1 RdCEn t2 Ack t17 Diag Cached t1 t2 t1 t2 t1 t2 t1 t2 t17 I/D Start Extended RdCEn Read Address Sample RdCEn Sample RdCEn Sample RdCEn Sample RdCEn Data Data Data Data 2905 drw 20 Figure 16(a). Quad Word Read to 16-bit wide Memory Port 25 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE Refill/ Fixup Stall Stall Word 0 PhiClk Refill/ Stream/ Fixup Word 1 Refill/ Stream/ Fixup Word 2 Refill/ Stream/ Fixup Word 3 SysClk t15 Rd t1a A/D(31:0) Halfword 4 t1a Halfword 5 t1a Halfword 6 t1a Halfword 7 t14 t2a Addr(3:1) '100' '101' t2a '110' t2a '111' t2a t16 ALE t16 t16 t16 BE16(1:0) '00' '00' '00' '00' t16 DataEn t16 t16 t16 t15 t49 ExtDataEn Burst t7b Last t50 MemStrobe t51 IOStrobe t1 RdCEn t2 Ack t17 Diag Ack/ RdCEn I/D t50 t51 t51 t50 t51 t15 t1 t2 t1 t2 t1 t2 Sample RdCEn Sample RdCEn Sample RdCEn Sample New Data Data Data Transaction Data 2905 drw 21 Figure 16(b). End of Quad Word read from 16-bit Wide Memory Port 26 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE SysClk t7 Wr t14 A/D(31:0) t16 Addr(3:2) t8 ALE t49 ExtDataEn t7 WrNear t7b Last t51 MemStrobe t50 t15 IOStrobe t47 t1 Ack Start Extended Data Out/ Write Address Ack? Ack? t2 Ack Negate New Write Transfer t15 t11 Word Address t15 t7a Addr BE t19 Data Output t14 t16 2905 drw 22 Figure 17. Basic Write to 32-bit Memory Port 27 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE SysClk t7 Wr t14 A/D(31:0) t16 Addr(3:0) t8 ALE t49 ExtDataEn t7 WrNear t7b Last t50 MemStrobe t51 t47 IOStrobe t1 Ack Start Extended Write Address t2 Ack t2 Ack t2 Ack Negate New Write Transaction 2905 drw 23 t15 t7a Addr Byte N Byte N+1 Byte N+2 t14 t19 'nnnn' t19 'nnnn+1' t19 'nnnn+2' t9 t16 t16 t16 t48 t15 t52 t50 t51 t52 t50 t51 t15 t1 t1 Figure 18. Tri-Byte Mini-burst Write to 8-bit Port 28 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE SysClk t2 t1 BusGnt t5 t3 BusReq A/D(31:0) Addr(3:0) Diag Rd Wr ALE Burst/ WrNear Last, BE16(1:0), MemStrobe IOStrobe t45 ExtDataEn TC 2905 drw 24 Figure 19. Request and Relinquish of R3041 Bus to External Master 29 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE SysClk BusReq t2 t1 t6 t4 BusGnt A/D(31:0) Addr(3:0) Diag Rd Wr ALE Burst/ WrNear Last, BE16(1:0) MemStrobe IOStrobe t46 ExtDataEn TC 2905 drw 25 Figure 20. R3041 Regaining Bus Mastership 30 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE SysClk CPU Bus Request BusReq t1 t2 t4 A/D(31:0) t6 BusGnt 2905 drw 26 Figure 21. R3041 DMA Pulse Protocol Run Cycle Phi Exception Vector SysClk SInt(n) t28 t29 2905 drw 27 Figure 22. Synchronized Interrupt Input Timing Run Cycle Phi Exception Vector SysClk Int(n) t 30 t 31 2905 drw 28 Figure 23. Direct Interrupt Input Timing Run Cycle Phi Capture BrCond BCzT/F Instruction SysClk SBrCond(n) t 28 t 29 2905 drw 29 Figure 24. Synchronized Branch Condition Input Timing 31 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE SysClk t7 TC Figure 25. t15 2905 drw 30 TC Output TC 84 LEAD PLCC (SQUARE) D D1 45° x .045 A A1 PIN 1 C D3/E3 E1 E b1 B D2/E2 e C1 SEATING PLANE 2874 drw 02 2905 drw 31 DWG # # of Leads Symbol A A1 B b1 C C1 D D1 D2/E2 D3/E3 E E1 e ND/NE 1.185 1.150 Min. 165 .095 .026 .013 .020 .008 1.185 1.150 1.090 J84-1 84 Max. .180 .115 .032 .021 .040 .012 1.195 1.156 1.130 1.000 REF 1.195 1.156 .050 BSC 21 2905 tbl 13 NOTES: 1. All dimensions are in inches, unless otherwise noted. 2. BSC—Basic lead Spacing between Centers. 3. D & E do not include mold flash or protutions. 4. Formed leads shall be planar with respect to one another and within .004” at the seating plane. 5. ND & NE represent the number of leads in the D & E directions respectively. 6. D1 & E1 should be measured from the bottom of the package. 7. PLCC is pin & form compatible with MQUAD; the MQUAD package is used in other RISController family members. 32 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE 100-PIN TQFP Draft Angle = 12° 100 A1 1 A2 100-Pin TQFP 0.30 Rad Typ. E1 E 0.20 Rad Typ. 6° ± 4° A D1 D L B Max 0.102 Lead Coplanarity Standoff 0.05 Min e A3 DWG # # of Leads Symbol A A1 A2 D D1 E E1 L N e b ccc ddd R R1 θ θ1 θ2 c 0.17 — — 0.08 0.08 0 11.0 11.0 0.09 Min. — 0.5 1.35 15.75 13.95 15.75 13.95 0.45 TQFP 100 Max. 1.60 0.15 1.45 16.25 14.05 16.25 14.05 0.70 100 0.50BSC 0.27 0.08 0.08 0.20 — 7.0 13.0 13.0 0.16 2905 tbl 14 33 IDT79R3041 INTEGRATED RISController FOR LOW COST SYSTEMS COMMERCIAL TEMPERATURE RANGE ORDERING INFORMATION XXXXX IDT Device Type Speed Package Process/ Temp. Range Blank 'J' 'PF' '16' '20' '25' '33' 79R3041 79RV3041 Commercial Temperature Range 84-Pin PLCC 100-Pin TQFP 16.67MHz 20.00MHz 25.00MHz 33.00MHz 5.0V Integrated RISController for Low-Cost Systems 3.3V Integrated RISController for Low-Cost Systems 2905 drw 32 — XX X X VALID COMBINATIONS IDT 79R3041 - 16 79R3041 - 20 79R3041 - 25 79R3041 - 33 79RV3041 - 16 79RV3041 - 20 79RV3041 - 25 79RV3041 - 33 TQFP, PLCC Package TQFP, PLCC Package TQFP, PLCC Package PLCC Package Only TQFP, PLCC Package TQFP, PLCC Package TQFP, PLCC Package TQFP, PLCC Package 34
79R3041-25J 价格&库存

很抱歉,暂时无法提供与“79R3041-25J”相匹配的价格&库存,您可以联系我们找货

免费人工找货