Military grade C64x fixed point DSP
产品详细信息
参数
封装|引脚|尺寸
特性
- Highest-Performance Fixed-Point Digital Signal Processors (DSPs)
- 2-, 1.67-, 1.39-ns Instruction Cycle Time
- 600-MHz Clock Rate
- Eight 32-Bit Instructions/Cycle
- Twenty-Eight Operations/Cycle
- 4800 MIPS
- Fully Software-Compatible With C62x™
- C6414/15/16 Devices Pin-Compatible
- VelociTI.2™ Extensions to VelociTI™ Advanced Very-Long-Instruction-Word (VLIW) TMS320C64x™ DSP Core
- Eight Highly Independent Functional Units With VelociTI.2™ Extensions:
- Six ALUs (32-/40-Bit), Each Supports Single 32-Bit, Dual 16-Bit, or Quad 8-Bit Arithmetic per Clock Cycle
- Two Multipliers SupportFour 16 x 16-Bit Multiplies (32-Bit Results) per Clock Cycle or Eight 8 x 8-Bit Multiplies (16-Bit Results) per Clock Cycle
- Non-Aligned Load-Store Architecture
- 64 32-Bit General-Purpose Registers
- Instruction Packing Reduces Code Size
- All Instructions Conditional
- Eight Highly Independent Functional Units With VelociTI.2™ Extensions:
- Instruction Set Features
- Byte-Addressable (8-/16-/32-/64-Bit Data)
- 8-Bit Overflow Protection
- Bit-Field Extract, Set, Clear
- Normalization, Saturation, Bit-Counting
- VelociTI.2™ Increased Orthogonality
- Viterbi Decoder Coprocessor (VCP) [C6416]
- Supports Over 500 7.95-Kbps AMR
- Programmable Code Parameters
- Turbo Decoder Coprocessor (TCP) [C6416]
- Supports up to Six 2-Mbps 3GPP (6 Iterations)
- Programmable Turbo Code and Decoding Parameters
- L1/L2 Memory Architecture
- 128K-Bit (16K-Byte) L1P Program Cache (Direct Mapped)
- 128K-Bit (16K-Byte) L1D Data Cache (2-Way Set-Associative)
- 8M-Bit (1024K-Byte) L2 Unified Mapped RAM/Cache (Flexible Allocation)
- Two External Memory Interfaces (EMIFs)
- One 64-Bit (EMIFA), One 16-Bit (EMIFB)
- Glueless Interface to Asynchronous Memories (SRAM and EPROM) and Synchronous Memories (SDRAM, SBSRAM, ZBT SRAM, and FIFO)
- 1280M-Byte Total Addressable External Memory Space
- Enhanced Direct-Memory-Access (EDMA) Controller (64 Independent Channels)
- Host-Port Interface (HPI)
- User-Configurable Bus Width (32-/16-Bit)
- 32-Bit/33-MHz, 3.3-V PCI Master/Slave Interface Conforms to PCI Specification 2.2 [C6415/C6416 ]
- Three PCI Bus Address Registers:
Prefetchable Memory
Non-Prefetchable Memory I/O - Four-Wire Serial EEPROM Interface
- PCI Interrupt Request Under DSP Program Control
- DSP Interrupt Via PCI I/O Cycle
- Three PCI Bus Address Registers:
- Three Multichannel Buffered Serial Ports
- Direct Interface to T1/E1, MVIP, SCSA Framers
- Up to 256 Channels Each
- ST-Bus-Switching-, AC97-Compatible
- Serial Peripheral Interface (SPI) Compatible (Motorola™)
- Three 32-Bit General-Purpose Timers
- Universal Test and Operations PHY Interface for ATM (UTOPIA) [C6415/C6416]
- UTOPIA Level 2 Slave ATM Controller
- 8-Bit Transmit and Receive Operations up to 50 MHz per Direction
- User-Defined Cell Format up to 64 Bytes
- Sixteen General-Purpose I/O (GPIO) Pins
- Flexible PLL Clock Generator
- IEEE-1149.1 (JTAG
) Boundary-Scan-Compatible
- 570-Pin Grid Array (PGA) Package (GAD Suffix)
- 0.13-µm/6-Level Cu Metal Process (CMOS)
- 3.3-V I/Os, 1.4-V Internal
C62x, VelociTI.2, VelociTI, and TMS320C64x are trademarks of Texas Instruments.
Motorola is a trademark of Motorola, Inc. IEEE Standard 1149.1-1990 Standard-Test-Access Port and Boundary Scan Architecture.
TMS320C6000, C64x, and C6000 are trademarks of Texas Instruments.
Windows is a registered trademark of the Microsoft Corporation.
All trademarks are the property of their respective owners. Throughout the remainder of this document, the SMJ320C6414, SMJ320C6415, and SMJ320C6416 shall be referred to as SMJ320C64x or C64x where generic, and where specific, their individual full device part numbers will be used or abbreviated as C6414, C6415, or C6416.
These C64x™ devices have two EMIFs (64-bit EMIFA and 16-bit EMIFB). The prefix "e;A"e; in front of a signal name indicates it is an EMIFA signal whereas a prefix "e;B"e; in front of a signal name indicates it is an EMIFB signal. Throughout the rest of this document, in generic EMIF areas of discussion, the prefix "e;A"e; or "e;B"e; may be omitted from the signal name.
描述
The TMS320C64x DSPs (including the SMJ320C6414, SMJ320C6415, and SMJ320C6416 devices) are the
highest-performance fixed-point DSP generation in the TMS320C6000 DSP platform. The TMS320C64x
(C64x) device is based on the second-generation high-performance, advanced VelociTI
very-long-instruction-word (VLIW) architecture (VelociTI.2) developed by Texas Instruments (TI), making
these DSPs an excellent choice for multichannel and multifunction applications. The C64x is a
code-compatible member of the C6000 DSP platform.
With performance of up to 5760 million instructions per second (MIPS) at a clock rate of 720 MHz, the C64x devices offer cost-effective solutions to high-performance DSP programming challenges. The C64x DSPs possess the operational flexibility of high-speed controllers and the numerical capability of array processors. The C64x DSP core processor has 64 general-purpose registers of 32-bit word length and eight highly independent functional unitstwo multipliers for a 32-bit result and six arithmetic logic units (ALUs) with VelociTI.2 extensions. The VelociTI.2 extensions in the eight functional units include new instructions to accelerate the performance in key applications and extend the parallelism of the VelociTI architecture. The C64x can produce four 32-bit multiply-accumulates (MACs) per cycle for a total of 2400 million MACs per second (MMACS), or eight 8-bit MACs per cycle for a total of 4800 MMACS. The C64x DSP also has application-specific hardware logic, on-chip memory, and additional on-chip peripherals similar to the other C6000 DSP platform devices.
The C6416 device has two high-performance embedded coprocessors [Viterbi Decoder Coprocessor (VCP) and Turbo Decoder Coprocessor (TCP)] that significantly speed up channel-decoding operations on-chip. The VCP operating at CPU clock divided-by-4 can decode over 500 7.95-Kbps adaptive multi-rate (AMR) [K = 9, R = 1/3] voice channels. The VCP supports constraint lengths K = 5, 6, 7, 8, and 9, rates R = 1/2, 1/3, and 1/4, and flexible polynomials, while generating hard decisions or soft decisions. The TCP operating at CPU clock divided-by-2 can decode up to thirty-six 384-Kbps or six 2-Mbps turbo encoded channels (assuming 6 iterations). The TCP implements the max*log-map algorithm and is designed to support all polynomials and rates required by Third-Generation Partnership Projects (3GPP and 3GPP2), with fully programmable frame length and turbo interleaver. Decoding parameters such as the number of iterations and stopping criteria are also programmable. Communications between the VCP/TCP and the CPU are carried out through the EDMA controller.
The C64x uses a two-level cache-based architecture and has a powerful and diverse set of peripherals. The Level 1 program cache (L1P) is a 128-Kbit direct mapped cache and the Level 1 data cache (L1D) is a 128-Kbit 2-way set-associative cache. The Level 2 memory/cache (L2) consists of an 8-Mbit memory space that is shared between program and data space. L2 memory can be configured as mapped memory or combinations of cache (up to 256K bytes) and mapped memory. The peripheral set includes three multichannel buffered serial ports (McBSPs); an 8-bit Universal Test and Operations PHY Interface for Asynchronous Transfer Mode (ATM) Slave [UTOPIA Slave] port (C6415/C6416 only); three 32-bit general-purpose timers; a user-configurable 16-bit or 32-bit host-port interface (HPI16/HPI32); a peripheral component interconnect (PCI) [C6415/C6416 only]; a general-purpose input/output port (GPIO) with 16 GPIO pins; and two glueless external memory interfaces (64-bit EMIFA and 16-bit EMIFB), both of which are capable of interfacing to synchronous and asynchronous memories and peripherals.
The C64x has a complete set of development tools which includes: an advanced C compiler with C64x-specific enhancements, an assembly optimizer to simplify programming and scheduling, and a Windows debugger interface for visibility into source code execution.
技术文档
类型 | 标题 | 下载最新的英文版本 | 日期 | |
---|---|---|---|---|
* | 数据表 | SMJ320C6414, SMJ320C6415, SMJ320C6416 Fixed-Point Digital Signal Processors 数据表 (Rev. A) | 2004年 3月 31日 | |
* | 勘误表 | TMS320C6414/C6415/C6416 Silicon Errata (Silicon Rev. 1.0,1.01,1.02,1.03,1.1,2.0) (Rev. T) | 2007年 8月 1日 | |
技术文章 | Bringing the next evolution of machine learning to the edge | 2018年 11月 27日 | ||
技术文章 | Industry 4.0 spelled backward makes no sense – and neither does the fact that you haven’t heard of TI’s newest processor yet | 2018年 10月 30日 | ||
技术文章 | How quality assurance on the Processor SDK can improve software scalability | 2018年 8月 22日 | ||
技术文章 | Clove: Low-Power video solutions based on Sitara™ AM57x processors | 2016年 7月 21日 | ||
应用手册 | Power Consumption Guide for the C66x | 2011年 10月 6日 |
设计与开发
有关其他条款或所需资源,请点击下面的任何链接来查看详情页面。硬件开发
说明
XDS560v2 System Trace 是 XDS560v2 系列高性能 TI 处理器调试探针(仿真器)的第一种型号。XDS560v2 是 XDS 系列调试探针中性能最高的一款,同时支持传统 JTAG 标准 (IEEE1149.1) 和 cJTAG (IEEE1149.7)。
XDS560v2 System Trace 在其巨大的外部存储器缓冲区中加入了系统引脚跟踪。这种外部存储器缓冲区适用于指定的 TI 器件,通过捕获相关器件级信息,获得准确的总线性能活动和吞吐量,并对内核和外设进行电源管理。此外,对于带有嵌入式缓冲跟踪器 (ETB) 的所有 ARM 和 DSP 处理器,所有 XDS 调试探针均支持内核和系统跟踪。
Blackhawk XDS560v2 System Trace 通过 MIPI HSPT 60 引脚连接器(带有适合 TI 14 引脚、TI 20 引脚和 ARM 20 (...)
特性
XDS560v2 是 XDS560 系列高性能 TI 处理器调试探针(仿真器)的最新型号。XDS560v2 具有整个系列中最快的速度和最多的功能,对于 TI 微控制器、处理器和无线连接微控制器的调试来说,它是最全面的解决方案。
XDS560v2 是 XDS560 调试探针系列中最先提供系统跟踪 (STM) 功能的一款,这种类型的跟踪可以通过捕获系统事件(例如处理内核的状态、内部总线和外设)来监控整个设备。大多数 XDS560v2 模型还提供系统引脚跟踪模式,在这种模式中,系统跟踪数据被送到 XDS560v2 内的外部存储器缓冲区 (128MB),因此能够捕获大量系统事件。系统引脚跟踪数据连接需要通过额外的接线连接 JTAG 连接器。
在 XDS560 调试探针系列中,XDS560v2 PRO TRACE 是提供内核引脚跟踪功能(指令和数据)的第二代产品,这种跟踪可以捕获内核执行的所有指令并将其发送到 XDS560v2 PRO TRACE 内的外部存储器缓冲区 (1GB)。内核引脚跟踪并不干扰系统的实时行为,而且可以捕获更多的指令。内核引脚跟踪数据连接需要通过额外的接线连接 JTAG 连接器。
为了支持所有类型的引脚跟踪(指令和系统),XDS560v2 的所有型号都提供标准的 60 引脚 MIPI HSPT 连接器作为与目标之间的主要 JTAG 连接。此外,所有型号都提供针对 TI 和 ARM 标准 JTAG 连接器的模块化目标适配器(提供的适配器因型号而异)。
XDS560v2 支持传统的 IEEE1149.1 (JTAG) 仿真和 IEEE1149.7 (cJTAG),运行时的 JTAG 接口电平为 1.2V 至 +4.1V。
与传统 JTAG 相比,紧凑 JTAG (cJTAG) 有巨大的进步;因为它仅需使用两个引脚即可支持所有功能,可用于某些指定的 TI 无线连接微控制器中。
所有 XDS560v2 (...)
说明
XDS560v2 System Trace 是 XDS560v2 系列高性能 TI 处理器调试探针(仿真器)的第一种型号。XDS560v2 是 XDS 系列调试探针中性能最高的一款,同时支持传统 JTAG 标准 (IEEE1149.1) 和 cJTAG (IEEE1149.7)。
XDS560v2 System Trace 在其巨大的外部存储器缓冲区中加入了系统引脚跟踪。这种外部存储器缓冲区适用于指定的 TI 器件,通过捕获相关器件级信息,获得准确的总线性能活动和吞吐量,并对内核和外设进行电源管理。此外,对于带有嵌入式缓冲跟踪器 (ETB) 的所有 ARM 和 DSP 处理器,所有 XDS 调试探针均支持内核和系统跟踪。
Spectrum Digital XDS560v2 System Trace 通过 MIPI HSPT 60 引脚连接器(适合 TI 14 引脚、TI 20 引脚、ARM 20 引脚和 TI 60 (...)
特性
XDS560v2 是 XDS560 系列高性能 TI 处理器调试探针(仿真器)的最新型号。XDS560v2 具有整个系列中最快的速度和最多的功能,对于 TI 微控制器、处理器和无线连接微控制器的调试来说,它是最全面的解决方案。
XDS560v2 是 XDS560 调试探针系列中最先提供系统跟踪 (STM) 功能的一款,这种类型的跟踪可以通过捕获系统事件(例如处理内核的状态、内部总线和外设)来监控整个设备。大多数 XDS560v2 模型还提供系统引脚跟踪模式,在这种模式中,系统跟踪数据被送到 XDS560v2 内的外部存储器缓冲区 (128MB),因此能够捕获大量系统事件。系统引脚跟踪数据连接需要通过额外的接线连接 JTAG 连接器。
在 XDS560 调试探针系列中,XDS560v2 PRO TRACE 是提供内核引脚跟踪功能(指令和数据)的第二代产品,这种跟踪可以捕获内核执行的所有指令并将其发送到 XDS560v2 PRO TRACE 内的外部存储器缓冲区 (1GB)。内核引脚跟踪并不干扰系统的实时行为,而且可以捕获更多的指令。内核引脚跟踪数据连接需要通过额外的接线连接 JTAG 连接器。
为了支持所有类型的引脚跟踪(指令和系统),XDS560v2 的所有型号都提供标准的 60 引脚 MIPI HSPT 连接器作为与目标之间的主要 JTAG 连接。此外,所有型号都提供针对 TI 和 ARM 标准 JTAG 连接器的模块化目标适配器(提供的适配器因型号而异)。
XDS560v2 支持传统的 IEEE1149.1 (JTAG) 仿真和 IEEE1149.7 (cJTAG),运行时的 JTAG 接口电平为 1.2V 至 +4.1V。
与传统 JTAG 相比,紧凑 JTAG (cJTAG) 有巨大的进步;因为它仅需使用两个引脚即可支持所有功能,可用于某些指定的 TI 无线连接微控制器中。
所有 XDS560v2 (...)
软件开发
特性
Optimized DSP routines including functions for:
- Adaptive filtering
- Correlation
- FFT
- Filtering and convolution: FIR, biquad, IIR, convolution
- Math: Dot products, max value, min value, etc.
- Matrix operations
设计工具和仿真
特性
- Supports many TI processors including Sitara and Jacinto Processors and DSPs
- Search by type of product, TI devices supported, or country
- Links and contacts for quick engagement
- Third-party companies located around the world
CAD/CAE 符号
封装 | 引脚 | 下载 |
---|---|---|
FCPGA (GAD) | 570 | 了解详情 |
订购与质量
- RoHS
- REACH
- 器件标识
- 引脚镀层/焊球材料
- MSL 等级/回流焊峰值温度
- MTBF/FIT 估算
- 材料成分
- 认证摘要
- 持续可靠性监测