Texas Instruments TMS320C6457 manual Hhwil

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HPI Operation

Figure 3. Example of Host-DSP Signal Connections When the HAS Signal is Tied High

in the 32-Bit Multiplexed Mode

Host

Address or I/O

Read/Write

Chip select

Data strobeA

Data/address

Ready

Interrupt

Logic high 2

No connect

Logic high

32

DSP

HPI

HAS

HCNTL[1:0]

HHWIL

HR/W

HCS

HDS1

HDS2

HD[31:0]

HRDY

HINT

A Data strobing options are given in Section 3.3.

Figure 4. Example of Host-DSP Signal Connections When Using the HAS Signal

in the 16-Bit Multiplexed Mode

Host

Address latch enable

Read/Write

Chip select

Data strobeA

Data/address

Ready

Interrupt

DSP

 

 

HPI

 

 

HAS

 

2

HCNTL[1:0]

 

 

 

 

HHWIL

 

 

HR/W

Logic

 

HCS

 

HDS1

high

 

 

 

 

 

HDS2

No

16

HD[31:16]

 

connect

 

 

 

 

16

HD[15:0]

 

 

 

 

HRDY

 

 

HINT

A Data strobing options are given in Section 3.3.

SPRUGK7A –March 2009 –Revised July 2010

Host Port Interface (HPI)

13

Copyright © 2009–2010, Texas Instruments Incorporated

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Contents Users Guide SPRUGK7A -March 2009 -Revised July HDS2 HDS1 HCS Appendix aHas List of Figures List of Tables Notational Conventions About This ManualRelated Documentation From Texas Instruments Introduction to the HPI Summary of the HPI Registers HPI Signals Summary of the HPI SignalsSummary of HPI Registers Hstrb HR/WI Hhwili HasiSingle-HPIA Mode Using the Address RegistersDual-HPIA Mode HPI Operation Host-HPI Signal ConnectionsHhwil HPI Configuration and Data Flow Available Host Data Strobe Pins Options for Connecting Host and HPI Data Strobe PinsHDS2, HDS1, and HCS Data Strobing and Chip Selection Cycle Types Selectable With the Hcntl and HR/W Signals Access Types Selectable by the Hcntl SignalsHCNTL10 and HR/W Indicating the Cycle Type Cycle TypeHas Forcing the HPI to Latch Control Information Early Hrdy a Hhwil HCS HasHrdya Hhwil HCS Has HR/WHstrb HR/W Performing a Multiplexed Access Without hasBit Multiplexed Mode Host Write Cycle With has Tied High Hardware Handshaking Using the HPI-Ready Hrdy Signal Single-Halfword Hpic Cycle in the 16-Bit Multiplexed ModeHrdy Hrdy Behavior During 16-Bit Multiplexed Read OperationsHR/W Hhwil Hrdy Behavior During 16-Bit Multiplexed Write OperationsHrdy Behavior During 32-Bit Multiplexed Read Operations Hpia Write Hrdy Behavior During 32-Bit Multiplexed Write OperationsHpid Read Hpia Write HPID+ ReadsHpia Write Hpid Write Hpia Write HPID+ Writes Polling the Hrdy Bit Software Handshaking Using the HPI Ready Hrdy BitDspint Bit Host-to-CPU Interrupts Interrupts Between the Host and the CPUHint Bit CPU-to-Host Interrupts DSPINT=0CPU-to-Host Interrupt State Diagram Read Bursting FIFOs and BurstingWrite Bursting Fifo Flush Conditions Fifo Behavior When a Hardware Reset or Software Reset OccursSoftware Reset Considerations Emulation and Reset ConsiderationsHardware Reset Considerations Emulation ModesIntroduction HPI RegistersHost Port Interface HPI Registers Soft Free R/W-0 R/W-0 Power and Emulation Management Register PwremumgmtBit Field Value Description SoftHost Port Interface Control Register Hpic Fetch DualhpiaFor host write cycle HPID/HPIC/HPIAR/HPIAWAddress Host Port Interface Address Registers Hpiaw and HpiarBit Field Value Description 31-0 Data Register Hpid Field Descriptions Data Register HpidData HPI dataTMS320C6457 HPI Revision History Appendix a Revision HistorySeeAdditions/Modifications/Deletions Rfid Products Applications

TMS320C6457 specifications

The Texas Instruments TMS320C6457 is a high-performance digital signal processor (DSP) designed for demanding applications in telecommunications, industrial control, and video processing. As part of the TMS320C6000 family, the C6457 combines advanced features with impressive processing capabilities, making it a popular choice among developers looking for efficient and robust solutions.

One of the key features of the TMS320C6457 is its architecture, which is based on the super Harvard architecture. This design separates program and data memory paths, allowing for parallel instruction execution. The C6457 operates at clock speeds of up to 1 GHz, enabling it to deliver peak performance of over 6,000 MIPS (Million Instructions Per Second) and 12,000 MADDs (Multiply-Accumulate operations per second). Such high throughput makes the C6457 suitable for real-time processing applications that require rapid data handling.

The C6457 DSP integrates a rich set of on-chip resources, including up to 1MB of on-chip SRAM, which serves as a fast cache for data and instructions. The device features multiple high-speed interfaces, such as 10/100/1000 Ethernet, Serial RapidIO, and PCI-Express, facilitating seamless connectivity with other devices and systems. Furthermore, the TMS320C6457 supports various communication protocols, allowing it to adapt to a wide range of application scenarios.

In terms of power efficiency, the TMS320C6457 is designed with sophisticated power management features. It includes dynamic voltage and frequency scaling, which adjust power consumption based on workload requirements without compromising performance. This capability is particularly valuable in battery-operated devices or environments where thermal management is critical.

The TMS320C6457 also benefits from extensive software support, including the Texas Instruments DSP/BIOS real-time operating system and Code Composer Studio integrated development environment. Developers can leverage these tools for efficient code development, debugging, and system optimization. Additionally, Texas Instruments provides a range of libraries and algorithms optimized for the C6457, facilitating rapid application development.

Overall, the Texas Instruments TMS320C6457 DSP stands out due to its robust architecture, high processing capabilities, comprehensive connectivity options, and power management features. These attributes make it a versatile solution for a broad spectrum of applications in digital signal processing, where performance and efficiency are paramount. As technology continues to advance, the TMS320C6457 remains a relevant and potent option for developers seeking to push the boundaries of digital signal processing.