1 TMS320C6727B, TMS320C6726B, TMS320C6722B, TMS320C6720 DSPs
1.1 Features
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C672x: 32-/64-Bit 350-MHz Floating-Point DSPs Three Multichannel Audio Serial Ports Transmit/Receive Clocks up to 50 MHzUpgrades to C67x+ CPU From C67x™ DSP
Six Clock Zones and 16 Serial Data PinsGeneration:
Supports TDM, I2S, and Similar Formats 2X CPU Registers [64 General-Purpose]
DIT-Capable (McASP2) New Audio-Specific Instructions Compatible With the C67x CPU
Universal Host-Port Interface (UHPI) 32-Bit-Wide Data Bus for High BandwidthEnhanced Memory System
Muxed and Non-Muxed Address and Data 256K-Byte Unified Program/Data RAM 384K-Byte Unified Program/Data ROM
Two 10-MHz SPI Ports With 3-, 4-, and 5-Pin Single-Cycle Data Access From CPU Options Large Program Cache (32K Byte) Supports
Two Inter-Integrated Circuit (I2C) PortsRAM, ROM, and External Memory
Real-Time Interrupt Counter/WatchdogExternal Memory Interface (EMIF) Supports
Oscillator- and Software-Controlled PLL 133-MHz SDRAM (16- or 32-Bit)
Applications: Asynchronous NOR Flash, SRAM (8-,16-, or
Professional Audio32-Bit)
Mixers NAND Flash (8- or 16-Bit)
Effects BoxesEnhanced I/O System
Audio Synthesis High-Performance Crossbar Switch
Instrument/Amp Modeling Dedicated McASP DMA Bus
Audio Conferencing Deterministic I/O Performance
Audio BroadcastdMAX (Dual Data Movement Accelerator)
Audio EncoderSupports:
Emerging Audio Applications 16 Independent Channels
Biometrics Concurrent Processing of Two Transfer
MedicalRequests
Industrial 1-, 2-, and 3-Dimensional
Commercial or Extended TemperatureMemory-to-Memory andMemory-to-Peripheral Data Transfers
144-Pin, 0.5-mm, PowerPAD™ Thin Quad Circular Addressing Where the Size of a Flatpack (TQFP) [RFP Suffix]Circular Buffer (FIFO) is not Limited to 2
n
256-Terminal, 1.0-mm, 16x16 Array Plastic Ball Table-Based Multi-Tap Delay Read and
Grid Array (PBGA) [GDH and ZDH Suffixes]Write Transfers From/To a Circular Buffer
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of TexasInstruments semiconductor products and disclaimers thereto appears at the end of this document.C67x, PowerPAD, TMS320C6000, C6000, DSP/BIOS, XDS, TMS320 are trademarks of Texas Instruments.Philips is a registered trademark of Koninklijki Philips Electronics N.V.All other trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Copyright © 2006–2008, Texas Instruments IncorporatedProducts conform to specifications per the terms of the TexasInstruments standard warranty. Production processing does notnecessarily include testing of all parameters.
1.2 Description
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The TMS320C672x is the next generation of Texas Instruments' C67x generation of high-performance32-/64-bit floating-point digital signal processors. The TMS320C672x includes the TMS320C6727B,TMS320C6726B, TMS320C6722B, and TMS320C6720 devices.
(1)
Enhanced C67x+ CPU. The C67x+ CPU is an enhanced version of the C67x CPU used on the C671xDSPs. It is compatible with the C67x CPU but offers significant improvements in speed, code density, andfloating-point performance per clock cycle. At 350 MHz, the CPU is capable of a maximum performance of2800 MIPS/2100 MFLOPS by executing up to eight instructions (six of which are floating-pointinstructions) in parallel each cycle. The CPU natively supports 32-bit fixed-point, 32-bit single-precisionfloating-point, and 64-bit double-precision floating-point arithmetic.
Efficient Memory System. The memory controller maps the large on-chip 256K-byte RAM and 384K-byteROM as unified program/data memory. Development is simplified since there is no fixed division betweenprogram and data memory size as on some other devices.
The memory controller supports single-cycle data accesses from the C67x+ CPU to the RAM and ROM.Up to three parallel accesses to the internal RAM and ROM from three of the following four sources aresupported:
Two 64-bit data accesses from the C67x+ CPUOne 256-bit program fetch from the core and program cacheOne 32-bit data access from the peripheral system (either dMAX or UHPI)
The large (32K-byte) program cache translates to a high hit rate for most applications. This prevents mostprogram/data access conflicts to the on-chip memory. It also enables effective program execution from anoff-chip memory such as an SDRAM.
High-Performance Crossbar Switch. A high-performance crossbar switch acts as a central hub betweenthe different bus masters (CPU, dMAX, UHPI) and different targets (peripherals and memory). Thecrossbar is partially connected; some connections are not supported (for example, UHPI-to-peripheralconnections).
Multiple transfers occur in parallel through the crossbar as long as there is no conflict between busmasters for a particular target. When a conflict does occur, the arbitration is a simple and deterministicfixed-priority scheme.
The dMAX is given highest-priority since it is responsible for the most time-critical I/O transfers, followednext by the UHPI, and finally by the CPU.
dMAX Dual Data Movement Accelerator. The dMAX is a module designed to perform Data MovementAcceleration. The Data Movement Accelerator (dMAX) controller handles user-programmed data transfersbetween the internal data memory controller and the device peripherals on the C672x DSPs. The dMAXallows movement of data to/from any addressable memory space including internal memory, peripherals,and external memory.
The dMAX controller includes features such as the capability to perform three-dimensional data transfersfor advanced data sorting, and the capability to manage a section of the memory as a circular buffer/FIFOwith delay-tap based reading and writing of data. The dMAX controller is capable of concurrentlyprocessing two transfer requests (provided that they are to/from different source/destinations).
External Memory Interface (EMIF) for Flexibility and Expansion. The external memory interface on theC672x supports a single bank of SDRAM and a single bank of asynchronous memory. The EMIF datawidth is 16 bits wide on the C6726B, C6722B, and C6720 and 32 bits wide on the C6727B.
SDRAM support includes x16 and x32 SDRAM devices with 1, 2, or 4 banks.
The C6726B, C6722B, and C6720 support SDRAM devices up to 128M bits.
(1) Throughout the remainder of the document, TMS320C6727B (or C6727B), TMS320C6726B (or C6726B), TMS320C6722B (or C6722B),and/or TMS320C6720 (or C6720) will be referred to as TMS320C672x (or C672x).
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The C6727B extends SDRAM support to 256M-bit and 512M-bit devices.
Asynchronous memory support is typically used to boot from a parallel non-multiplexed NOR flash devicethat can be 8, 16, or 32 bits wide. Booting from larger flash devices than are natively supported by thededicated EMIF address lines is accomplished by using general-purpose I/O pins for upper address lines.
The asynchronous memory interface can also be configured to support 8- or 16-bit-wide NAND flash. Itincludes a hardware ECC calculation (for single-bit errors) that can operate on blocks of data up to512 bytes.
Universal Host-Port Interface (UHPI) for High-Speed Parallel I/O. The Universal Host-Port Interface(UHPI) is a parallel interface through which an external host CPU can access memories on the DSP.Three modes are supported by the C672x UHPI:Multiplexed Address/Data - Half-Word (16-bit-wide) Mode (similar to C6713)Multiplexed Address/Data - Full Word (32-bit-wide) ModeNon-Multiplexed Mode - 16-bit Address and 32-bit Data Bus
The UHPI can also be restricted to accessing a single page (64K bytes) of memory anywhere in theaddress space of the C672x; this page can be changed, but only by the C672x CPU. This feature allowsthe UHPI to be used for high-speed data transfers even in systems where security is an importantrequirement.
The UHPI is only available on the C6727B.
Multichannel Audio Serial Ports (McASP0, McASP1, and McASP2) - Up to 16 Stereo Channels I2S.The multichannel audio serial port (McASP) seamlessly interfaces to CODECs, DACs, ADCs, and otherdevices. It supports the ubiquitous IIS format as well as many variations of this format, including timedivision multiplex (TDM) formats with up to 32 time slots.
Each McASP includes a transmit and receive section which may operate independently or synchronously;furthermore, each section includes its own flexible clock generator and extensive error-checking logic.
As data passes through the McASP, it can be realigned so that the fixed-point representation used by theapplication code can be independent of the representation used by the external devices without requiringany CPU overhead to make the conversion.
The McASP is a configurable module and supports between 2 and 16 serial data pins. It also has theoption of supporting a Digital Interface Transmitter (DIT) mode with a full 384 bits of channel status anduser data memory.
McASP2 is not available on the C6722B and C6720.
Inter-Integrated Circuit Serial Ports (I2C0, I2C1). The C672x includes two inter-integrated circuit (I2C)serial ports. A typical application is to configure one I2C serial port as a slave to an external user-interfacemicrocontroller. The other I2C serial port may then be used by the C672x DSP to control externalperipheral devices, such as a CODEC or network controller, which are functionally peripherals of the DSPdevice.
The two I2C serial ports are pin-multiplexed with the SPI0 serial port.
Serial Peripheral Interface Ports (SPI0, SPI1). As in the case of the I2C serial ports, the C672x DSPalso includes two serial peripheral interface (SPI) serial ports. This allows one SPI port to be configured asa slave to control the DSP while the other SPI serial port is used by the DSP to control externalperipherals.
The SPI ports support a basic 3-pin mode as well as optional 4- and 5-pin modes. The optional pinsinclude a slave chip-select pin and an enable pin which implements handshaking automatically inhardware for maximum SPI throughput.
The SPI0 port is pin-multiplexed with the two I2C serial ports (I2C0 and I2C1). The SPI1 serial port ispin-multiplexed with five of the serial data pins from McASP0 and McASP1.
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1.2.1 Device Compatibility
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Real-Time Interrupt Timer (RTI). The real-time interrupt timer module includes:Two 32-bit counter/prescaler pairsTwo input captures (tied to McASP direct memory access [DMA] events for sample rate measurement)Four compares with automatic update capabilityDigital Watchdog (optional) for enhanced system robustness
Clock Generation (PLL and OSC). The C672x DSP includes an on-chip oscillator that supports crystalsin the range of 12 MHz to 25 MHz. Alternatively, the clock can be provided externally through the CLKINpin.
The DSP includes a flexible, software-programmable phase-locked loop (PLL) clock generator. Threedifferent clock domains (SYSCLK1, SYSCLK2, and SYSCLK3) are generated by dividing down the PLLoutput. SYSCLK1 is the clock used by the CPU, memory controller, and memories. SYSCLK2 is used bythe peripheral subsystem and dMAX. SYSCLK3 is used exclusively for the EMIF.
The TMS320C672x floating-point digital signal processors are based on the new C67x+ CPU. This core iscode-compatible with the C67x CPU core used on the TMS320C671x DSPs, but with significantenhancements including additional floating-point instructions. See Section 2.2
4TMS320C6727B, TMS320C6726B, TMS320C6722B, TMS320C6720 DSPs Submit Documentation Feedback
1.3 Functional Block Diagram
Program/Data
RAM
256K Bytes
256
256 Program/Data
ROM Page0
256K Bytes
256 Program/Data
ROM Page1
128K Bytes
3232
DMPPMP
CSP 32
256
32K Bytes
Program
Cache
64
D1
Data
R/W
R/W
Data
D2 64
256
Program
FetchINTI/O
C67x+ CPU
Memory
Controller
32
High-Performance
Crossbar Switch 32
McASP DMA Bus
JTAG EMU
32
32
32
32
32
32
32
32
Peripheral Configuration Bus
EMIF
32
Events
In
32
MAX1MAX0
32
CONTROL
32
Interrupts
Out
I/O
dMAX
McASP0
16 Serializers
McASP1
6 Serializers
McASP2
2 Serializers
+ DIT
SPI1
SPI0
I2C1
I2C0
RTI32
UHPI
PLL
Peripheral Interrupt and DMA Events
32
32
32
32
32
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Figure 1-1 shows the functional block diagram of the C672x device.
A. UHPI is available only on the C6727B. McASP2 is not available on the C6722B and C6720.
Figure 1-1. C672x DSP Block Diagram
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Contents
TMS320C6727B, TMS320C6726B, TMS320C6722B, TMS320C6720Floating-Point Digital Signal Processors
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1 TMS320C6727B, TMS320C6726B, 4.4 Electrical Characteristics ............................ 34TMS320C6722B, TMS320C6720 DSPs ............... 1
4.5 Parameter Information .............................. 351.1 Features .............................................. 1
4.6 Timing Parameter Symbology ....................... 361.2 Description ............................................ 2
4.7 Power Supplies ...................................... 371.2.1 Device Compatibility ................................. 4
4.8 Reset ................................................ 381.3 Functional Block Diagram ............................ 5
4.9 Dual Data Movement Accelerator (dMAX) .......... 392 Device Overview ......................................... 7
4.10 External Interrupts ................................... 442.1 Device Characteristics ................................ 7
4.11 External Memory Interface (EMIF) .................. 452.2 Enhanced C67x+ CPU ............................... 8
4.12 Universal Host-Port Interface (UHPI) [C6727BOnly] ................................................. 562.3 CPU Interrupt Assignments ........................... 9
4.13 Multichannel Audio Serial Ports (McASP0, McASP1,2.4 Internal Program/Data ROM and RAM .............. 10
and McASP2) ........................................ 702.5 Program Cache ...................................... 11
4.14 Serial Peripheral Interface Ports (SPI0, SPI1) ...... 822.6 High-Performance Crossbar Switch ................. 12
4.15 Inter-Integrated Circuit Serial Ports (I2C0, I2C1) ... 952.7 Memory Map Summary ............................. 15
4.16 Real-Time Interrupt (RTI) Timer With Digital2.8 Boot Modes .......................................... 16
Watchdog ............................................ 992.9 Pin Assignments .................................... 19
4.17 External Clock Input From Oscillator or CLKIN Pin 1022.10 Development ........................................ 26
4.18 Phase-Locked Loop (PLL) ......................... 1043 Device Configurations ................................. 30
5 Application Example ................................. 1073.1 Device Configuration Registers ..................... 30
6 Revision History ...................................... 1083.2 Peripheral Pin Multiplexing Options ................. 30
7 Mechanical Data ....................................... 1093.3 Peripheral Pin Multiplexing Control ................. 31
7.1 Package Thermal Resistance Characteristics ..... 1094 Peripheral and Electrical Specifications ........... 33
7.2 Supplementary Information About the 144-Pin RFP4.1 Electrical Specifications ............................. 33
PowerPAD™ Package ............................. 1104.2 Absolute Maximum Ratings ......................... 33
7.3 Packaging Information ............................. 1104.3 Recommended Operating Conditions ............... 33
Contents 6Submit Documentation Feedback
2 Device Overview
2.1 Device Characteristics
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Table 2-1 provides an overview of the C672x DSPs. The table shows significant features of each device,including the capacity of on-chip memory, the peripherals, the execution time, and the package type withpin count.
Table 2-1. Characteristics of the C672x Processors
HARDWARE FEATURES C6727B C6726B C6722B C6720
dMAX 1EMIF 1 (32-bit) 1 (16-bit) 1 (16-bit) 1 (16-bit)Peripherals
UHPI 1 0 0 0Not all peripheral pins are
3available at the same
McASP 3 2 2(McASP2 DIT only)time. (For more details,see the Device
SPI 2Configurations section.)
I2C 2RTI 132KB Program 32KB Program 32KB Program 32KB ProgramCache Cache Cache CacheOn-Chip Memory Size (KB)
256KB RAM 256KB RAM 128KB RAM 64KB RAM384KB ROM 384KB ROM 384KB ROM 384KB ROMControl Status RegisterCPU ID + CPU Rev ID 0x0300(CSR.[31:16])Frequency MHz 350, 300, 275, 250 266, 225 250, 225, 200 2002.8 ns(C6727B-350) 4 ns3.3 ns 3.75 ns (C6722B-250)(C6727B-300) (C6726B-266) 4.4 ns 5 nsCycle Time ns
3.6 ns 4.4 ns (C6722B A-225)
(1)
(C6720-200)(C6727B-275) (C6726B A-225)
(1)
5 ns4 ns (C6722B-200)(C6727B A-250)
(1)
133 (266-MHz
CPU Frequency)EMIF Frequency MHz 133 100 100100 (225-MHz
CPU Frequency)1.4 V(C6727B-350)
1.2 VCore (V) 1.2 V(C6727B-300)Voltage
(C6727B-275)
(C6727B A-250)
(1)
I/O (V) 3.3 VPrescaler /1, /2, /3, ..., /32Clock Generator Options Multiplier x4, x5, x6, ..., x25Postscaler /1, /2, /3, ..., /32256-Terminal
PBGA (GDH)17 x 17 mm 256-Terminal Green PBGAPackages (see Section 7 )
(ZDH)
144-Pin PowerPAD 144-Pin PowerPAD 144-Pin PowerPAD20 x 20 mm Green TQFP Green TQFP Green TQFP(RFP) (RFP) (RFP)Process Technology µm 0.13 µm
(1) TMS320C6727B A-250, TMS320C6726B A-225, and TMS320C6722B A-225 are extended-temperature devices.
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2.2 Enhanced C67x+ CPU
.D1 .M1 .S1 .L1
Register File A
Data Path A
Cross
Paths
.D2 .M2 .S2 .L2
Register File B
Data Path B
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Table 2-1. Characteristics of the C672x Processors (continued)
HARDWARE FEATURES C6727B C6726B C6722B C6720
Product Preview (PP),Advance Information (AI),Product Status PD
(2)or
Production Data (PD)
(2) PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of TexasInstruments standard warranty. Production processing does not necessarily include testing of all parameters.
The TMS320C672x floating-point digital signal processors are based on the new C67x+ CPU. This core iscode-compatible with the C67x CPU core used on the TMS320C671x DSPs, but with significantenhancements including an increase in core operating frequency from 225 MHz to 350 MHz
(3)
whileoperating at 1.2 V (1.4 V for C6727B-350).
The CPU fetches 256-bit-wide advanced very-long instruction word (VLIW) fetch packets that arecomposed of variable-length execute packets. The execute packets can supply from one to eight 32-bitinstructions to the eight functional units during every clock cycle. The variable-length execute packets area key memory-saving feature, distinguishing the C67x CPU from other VLIW architectures. Additionally,execute packets can now span fetch packets, providing a code size improvement over the C67x CPUcore.
The CPU features two data paths, shown in Figure 2-1 , each composed of four functional units (.D, .M, .S,and .L) and a register file. The .D unit in each data path is a data-addressing unit that is responsible for alldata transfers between the register files and the memory. The .M functional units are dedicated formultiplies, and the .S and .L functional units perform a general set of arithmetic, logical, and branchfunctions. All instructions operate on registers as opposed to data in memory, but results stored in the32-bit registers can be subsequently moved to memory as bytes, half-words, or words.
Figure 2-1. CPU Data Paths
The register file in each data path contains 32 32-bit registers for a total of 64 general-purpose registers.This doubles the number of registers found on the C67x CPU core, allowing the optimizing C compiler topipeline more complex loops by decreasing register pressure significantly.
The four functional units in each data path of the CPU can freely share the 32 registers belonging to thatdata path. Each data path also features a single cross path connected to the register file on the opposingdata path. This allows each data path to source one cross-path operand per cycle from the opposingregister file. On the C67x+ CPU, this single cross-path operand can be used by two functional units percycle, an improvement over the C67x CPU in which only one functional unit could use the cross-pathoperand. In addition, the cross-path register read(s) are not counted as part of the limit of four reads of thesame register in a single cycle.
The C67x+ CPU executes all C67x instructions plus new floating-point instructions to improveperformance specifically during audio processing. These new instructions are listed in Table 2-2 .(3) CPU speed is device-dependent. See Table 2-1 .
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2.3 CPU Interrupt Assignments
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Table 2-2. New Floating-Point Instructions for C67x+ CPU
FLOATING-POINTINSTRUCTION IMPROVESOPERATION
(1)
MPYSPDP SP x DP DP Faster than MPYDP.Improves high Q biquads (bass management) and FFT.MPYSP2DP SP x SP DP Faster than MPYDP.Improves Long FIRs (EQ).ADDSP (new to CPU “S” Unit) SP + SP SPADDDP (new to CPU “S” Unit) DP + DP DP
Now up to four floating-point add and subtract operations in parallel.Improves FFT performance and symmetric FIR.SUBSP (new to CPU “S” Unit) SP SP SPSUBDP (new to CPU “S” Unit) DP DP DP
(1) SP means IEEE Single-Precision (32-bit) operations and DP means IEEE Double-Precision (64-bit) operations.
Finally, two new registers, which are dedicated to communication with the dMAX unit, have been added tothe C67x+ CPU. These registers are the dMAX Event Trigger Register (DETR) and the dMAX EventStatus Register (DESR). They allow the CPU and dMAX to communicate without requiring any accessesto the memory system.
Table 2-3 lists the interrupt channel assignments on the C672x device. If more than one source is listed,the interrupt channel is shared and an interrupt on this channel could have come from any of the enabledperipherals on that channel.
The dMAX peripheral has two CPU interrupts dedicated to reporting FIFO status (INT7) and transfercompletion (INT8). In addition, the dMAX can generate interrupts to the CPU on lines INT9–13 and INT15in response to peripheral events. To enable this functionality, the associated Event Entry within the dMAXcan be programmed so that a CPU interrupt is generated when the peripheral event is received.
Table 2-3. CPU Interrupt Assignments
CPU INTERRUPT INTERRUPT SOURCE
INT0 RESETINT1 NMI (From dMAX or EMIF Interrupt)INT2 ReservedINT3 ReservedINT4 RTI Interrupt 0INT5 RTI Interrupts 1, 2, 3, and RTI Overflow Interrupts 0 and 1.INT6 UHPI CPU Interrupt (from External Host MCU)INT7 FIFO status notification from dMAXINT8 Transfer completion notification from dMAXINT9 dMAX event (0x2 specified in the dMAX interrupt event entry)INT10 dMAX event (0x3 specified in the dMAX interrupt event entry)INT11 dMAX event (0x4 specified in the dMAX interrupt event entry)INT12 dMAX event (0x5 specified in the dMAX interrupt event entry)INT13 dMAX event (0x6 specified in the dMAX interrupt event entry)INT14 I2C0, I2C1, SPI0, SPI1 InterruptsINT15 dMAX event (0x7 specified in the dMAX interrupt event entry)
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2.4 Internal Program/Data ROM and RAM
00 20
2707
2F
2808
0F
3F
38
37
30
1F
18
10
17
3F
38
37
30
1F
18
17
10
2F
28
27
20
0F
08
00
07
Byte
ROM Page 1
Base Address
0x0004 0000
ROM Page 0
Base Address
0x0000 0000
Bank
0Bank
1Bank
2Bank
3
13 33
10 30
17 37
14 34
1B 3B
18 38
1F 3F
1C 3C
RAM Page 0
Base Address
0x1000 0000
00 20
03 23
07
04
27
24
0B
08
2B
28
0F
0C
2F
2C
Byte
Bank
0Bank
1Bank
2Bank
3Bank
4Bank
5Bank
6Bank
7
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The organization of program/data ROM and RAM on C672x is simple and efficient. ROM is organized astwo 256-bit-wide pages with four 64-bit-wide banks. RAM is organized as a single 256-bit-wide page witheight 32-bit-wide banks.
The internal memory organization is illustrated in Figure 2-2 (ROM) and Figure 2-3 (RAM).
Figure 2-2. Program/Data ROM Organization
Figure 2-3. Program/Data RAM Organization
The C672x memory controller supports up to three parallel accesses to the internal RAM and ROM fromthree of the following four sources as long as there are no bank conflicts:Two 64-bit data accesses from the C67x+ CPUOne 256-bit-wide program fetch from the program cacheOne 32-bit data access from the peripheral system (either dMAX or UHPI)
A program cache miss is 256 bits wide and conflicts only with data accesses to the same page. Multipledata accesses to different pages, or to the same page but different banks will occur without conflict.
The organization of the C672x internal memory system into multiple pages (3 total) and a large number ofbanks (16 total) means that it is straightforward to optimize DSP code to avoid data conflicts. Severalfactors, including the large program cache and the partitioning of the memory system into multiple pages,minimize the number of program versus data conflicts.
The result is an efficient memory system which allows easy tuning towards the maximum possible CPUperformance.
The C672x ROM consists of a software bootloader plus additional software. Please refer to theC9230C100 TMS320C672x Floating-Point Digital Signal Processors ROM Data Manual (literature numberSPRS277) for more details on the ROM contents.
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2.5 Program Cache
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The C672x DSP executes code directly from a large on-chip 32K-byte program cache. The program cachehas these key features:Wide 256-bit path to internal ROM/RAMSingle-cycle access on cache hits2-cycle miss penalty to internal ROM/RAMCaches external memory as well as ROM/RAMDirect-mapped
Modes: Enable, Freeze, BypassSoftware invalidate to support code overlay
The program cache line size is 256 bits wide and is matched with a 256-bit-wide path between cache andinternal memory. This allows the program cache to fill an entire line (corresponding to eight C67x+ CPUinstructions) with only a single miss penalty of 2 cycles.
The program cache control registers are listed in Table 2-4 .
Table 2-4. Program Cache Control Registers
REGISTER NAME BYTE ADDRESS DESCRIPTION
L1PISAR 0x2000 0000 L1P Invalidate Start AddressL1PICR 0x2000 0004 L1P Invalidate Control Register
CAUTIONAny application which modifies the contents of program RAM (for example, a programoverlay) must invalidate the addresses from program cache to maintain coherency byexplicitly writing to the L1PISAR and L1PICR registers.
The Cache Mode (Enable, Freeze, Bypass) is configured through a CPU internal register (CSR, bits 7:5).These options are listed in Table 2-5 . Typically, only the Cache Enable Mode is used. But advanced usersmay utilize Freeze and Bypass modes to tune performance.
Table 2-5. Cache Modes Set Through PCC Field of CSR CPU Register on C672x
CPU CSR[7:5] CACHE MODE
000b Enable (Deprecated - Means direct mapped RAM on some C6000 devices)010b Enable - Cache is enabled, cache misses cause a line fill.011b Freeze - Cache is enabled, but contents are unchanged by misses.100b Bypass - Forces cache misses, cache contents frozen.Other Values Reserved - Not Supported
CAUTIONAlthough the reset value of CSR[7:5] (PCC field) is 000b, the value may be modifiedduring the boot process by the ROM code. Refer to the appropriate ROM data sheetfor more details. However, note that the cache may be disabled when control isactually passed to application code. Therefore, it may be necessary to write '010b' tothe PCC field to explicitly enable the cache at the start of application code.
CAUTIONChanging the cache mode through CSR[7:5] does not invalidate any lines already inthe cache. To invalidate the cache after modifications are made to program space, thecontrol registers L1PISAR and L1PICR must be used.
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2.6 High-Performance Crossbar Switch
SYSCLK3
SYSCLK1 SYSCLK2
SYSCLK3
BR3 BR4
2 1
Priority
EMIF
External
Memory
SDRAM/
Flash
Priority
21 3 4
T2
SYSCLK2
SYSCLK1
BR1
SYSCLK2
SYSCLK1
BR2
Program
Master
Port
(PMP)
CPU
Slave
Port
(CSP)
Data
Master
Port
(DMP)
Memory Controller
M1 T1 M2
Priority
1 2 3
PLL SPI0 I2C0 I2C1RTI SPI1
Peripheral Configuration Bus
McASP2McASP1McASP0
McASP DMA Bus
Priority
123
Priority
1 2
T4
T3
dMAX MAX0 Unit Master Port − High Priority
dMAX MAX1 Unit Master Port − Second Priority
Memory Controller DMP − Data Read/Write by CPU
UHPI Master Interface (External Host CPU)
UHPI
Universal Host-Port
Interface
M5
MAX0 MAX1
1 2 3
Priority
Config
dMAX
T5M3 M4
External
Host MCU Config
ROM RAM CPU Program
Cache
Crossbar
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The C672x DSP includes a high-performance crossbar switch that acts as a central hub between busmasters and targets. Figure 2-4 illustrates the connectivity of the crossbar switch.
Figure 2-4. Block Diagram of Crossbar Switch
As shown in Figure 2-4 , there are five bus masters:
M1 Memory controller DMP for CPU data accesses to peripherals and EMIF.M2 Memory controller PMP for program cache fills from the EMIF.M3 dMAX HiMAX master port for high-priority DMA accesses.M4 dMAX LoMAX master port for lower-priority DMA accesses.M5 UHPI master port for an external MCU to access on-chip and off-chip memories.
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The five bus masters arbitrate for five different target groups:
T1 On-chip memories through the CPU Slave Port (CSP).T2 Memories on the external memory interface (EMIF).T3 Peripheral registers through the peripheral configuration bus.T4 McASP serializers through the dedicated McASP DMA bus.T5 dMAX registers.
The crossbar switch supports parallel accesses from different bus masters to different targets. When twoor more bus masters contend for the same target beginning at the same cycle, then the highest-prioritymaster is given ownership of the target while the other master(s) are stalled. However, once ownership ofthe target is given to a bus master, it is allowed to complete its access before ownership is arbitratedagain. Following are two examples.
Example 1: Simultaneous accesses without conflictdMAX HiMAX accesses McASP Data Port for transfer of audio data.dMAX LoMAX accesses SPI port for control processing.UHPI accesses internal RAM through the CSP.CPU fills program cache from EMIF.
Example 2: Conflict over a shared resourcedMAX HiMAX accesses RTI port for McASP sample rate measurement.dMAX LoMAX accesses SPI port for control processing.
In Example 2, both masters contend for the same target, the peripheral configuration bus. The HiMAXaccess will be given priority over the LoMAX access.
The master priority is illustrated in Figure 2-4 by the numbers 1 through 4 in the bus arbiter symbols. Notethat the EMIF arbitration is distributed so that only one bridge crossing is necessary for PMP accesses.The effect is that PMP has 5th priority to the EMIF but lower latency.
A bus bridge is needed between masters and targets which run at different clock rates. The bus bridgecontains a small FIFO to allow the bridge to accept an incoming (burst) access at one clock rate and passit through the bridge to a target running at a different rate. Table 2-6 lists the FIFO properties of the fourbridges (BR1, BR2, BR3, and BR4) in Figure 2-4 .
Table 2-6. Bus Bridges
LABEL BRIDGE DESCRIPTION MASTER CLOCK TARGET CLOCK
BR1 DMP Bridge to peripherals, dMAX, EMIF SYSCLK1 SYSCLK2BR2 dMAX, UHPI to ROM/RAM (CSP) SYSCLK2 SYSCLK1BR3 PMP to EMIF SYSCLK1 SYSCLK3BR4 CPU, UHPI, and dMAX to EMIF SYSCLK2 SYSCLK3
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Figure 2-5 shows the bit layout of the device-level bridge control register (CFGBRIDGE) and Table 2-7contains a description of the bits.31 16Reserved
15 1 0
Reserved CSPRST
R/W, 1
LEGEND: R/W = Read/Write; R = Read only; - n= value after reset
Figure 2-5. CFGBRIDGE Register Bit Layout (0x4000 0024)
Table 2-7. CFGBRIDGE Register Bit Field Description (0x4000 0024)
BIT NO. NAME RESET VALUE READ WRITE DESCRIPTION
31:1 Reserved N/A N/A Reads are indeterminate. Only 0s should be written to these bits.0 CSPRST 1 R/W Resets the CSP Bridge (BR2 in Figure 2-4 ).1 = Bridge Reset Asserted0 = Bridge Reset Released
CAUTIONThe CSPRST bit must be asserted after any change to the PLL that affects SYSCLK1and SYSCLK2 and must be released before any accesses to the CSP bridge occurfrom either the dMAX or the UHPI.
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2.7 Memory Map Summary
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A high-level memory map of the C672x DSP appears in Table 2-8 . The base address of each region islisted. Any address past the end address must not be read or written. The table also lists whether theregions are word-addressable or byte- and word-addressable.
Table 2-8. C672x Memory Map
DESCRIPTION BASE ADDRESS END ADDRESS BYTE- OR WORD-ADDRESSABLE
Internal ROM Page 0 (256K Bytes) 0x0000 0000 0x0003 FFFF Byte and WordInternal ROM Page 1 (128K Bytes) 0x0004 0000 0x0005 FFFF Byte and WordInternal RAM Page 0 (256K Bytes) 0x1000 0000 0x1003 FFFF Byte and WordMemory and Cache Control Registers 0x2000 0000 0x2000 001F Word OnlyEmulation Control Registers (Do Not Access) 0x3000 0000 0x3FFF FFFF Word OnlyDevice Configuration Registers 0x4000 0000 0x4000 0083 Word OnlyPLL Control Registers 0x4100 0000 0x4100 015F Word OnlyReal-time Interrupt (RTI) Control Registers 0x4200 0000 0x4200 00A3 Word OnlyUniversal Host-Port Interface (UHPI) Registers 0x4300 0000 0x4300 0043 Word OnlyMcASP0 Control Registers 0x4400 0000 0x4400 02BF Word OnlyMcASP1 Control Registers 0x4500 0000 0x4500 02BF Word OnlyMcASP2 Control Registers 0x4600 0000 0x4600 02BF Word OnlySPI0 Control Registers 0x4700 0000 0x4700 007F Word OnlySPI1 Control Registers 0x4800 0000 0x4800 007F Word OnlyI2C0 Control Registers 0x4900 0000 0x4900 007F Word OnlyI2C1 Control Registers 0x4A00 0000 0x4A00 007F Word OnlyMcASP0 DMA Port (any address in this range) 0x5400 0000 0x54FF FFFF Word OnlyMcASP1 DMA Port (any address in this range) 0x5500 0000 0x55FF FFFF Word OnlyMcASP2 DMA Port (any address in this range) 0x5600 0000 0x56FF FFFF Word OnlydMAX Control Registers 0x6000 0000 0x6000 008F Word OnlyMAX0 (HiMAX) Event Entry Table 0x6100 8000 0x6100 807F Byte and WordReserved 0x6100 8080 0x6100 809FMAX0 (HiMAX) Transfer Entry Table 0x6100 80A0 0x6100 81FF Byte and WordMAX1 (LoMAX) Event Entry Table 0x6200 8000 0x6200 807F Byte and WordReserved 0x6200 8080 0x6200 809FMAX1 (LoMAX) Transfer Entry Table 0x6200 80A0 0x6200 81FF Byte and WordExternal SDRAM space on EMIF 0x8000 0000 0x8FFF FFFF Byte and WordExternal Asynchronous / Flash space on EMIF 0x9000 0000 0x9FFF FFFF Byte and WordEMIF Control Registers 0xF000 0000 0xF000 00BF Word Only
(1)
(1) The upper byte of the EMIF’s SDRAM Configuration Register (SDCR[31:24]) is byte-addressable to support placing the EMIF into theSelf-Refresh State without triggering the SDRAM Initialization Sequence.
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2.8 Boot Modes
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The C672x DSP supports only one hardware bootmode option, this is to boot from the internal ROMstarting at address 0x0000 0000. Other bootmode options are implemented by a software bootloaderstored in ROM. The software bootloader uses the CFGPIN0 and CFGPIN1 registers, which capture thestate of various device pins at reset, to determine which mode to enter. Note that in practice, only a fewpins are used by the software.
CAUTIONOnly an externally applied RESET causes the CFGPIN0 and CFGPIN1 registers torecapture their associated pin values. Neither an emulator reset nor a RTI resetcauses these registers to update.
The ROM bootmodes include:Parallel Flash on EM_CS[2]SPI0 or I2C1 master mode from serial EEPROMSPI0 or I2C1 slave mode from external MCUUHPI from an external MCU
Table 2-9 describes the required boot pin settings at device reset for each bootmode.
Table 2-9. Required Boot Pin Settings at Device Reset
BOOT MODE UHPI_HCS SPI0_SOMI SPI0_SIMO SPI0_CLK
UHPI 0 BYTEAD
(1)
FULL
(1)
NMUX
(1)
Parallel Flash 1 0 1 0SPI0 Master 1 0 0 1SPI0 Slave 1 0 1 1I2C1 Master 1 1 0 1I2C1 Slave 1 1 1 1
(1) When UHPI_HCS is 0, the state of the SPI0_SOMI, SPI0_SIMO, and SPI0_CLK pins is copied into the specified bits in the CFGHPIregister described in Table 4-14 .
Refer to the C9230C100 TMS320C672x Floating-Point Digital Signal Processor ROM Data Manual(literature number SPRS277) for details on supported bootmodes and their implementation.
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Figure 2-6 shows the bit layout of the CFGPIN0 register and Table 2-10 contains a description of the bits.31 8Reserved
76543210
PINCAP7 PINCAP6 PINCAP5 PINCAP4 PINCAP3 PINCAP2 PINCAP1 PINCAP0
LEGEND: R/W = Read/Write; R = Read only; - n= value after reset
Figure 2-6. CFGPIN0 Register Bit Layout (0x4000 0000)
Table 2-10. CFGPIN0 Register Bit Field Description (0x4000 0000)
BIT NO. NAME DESCRIPTION
31:8 Reserved Reads are indeterminate. Only 0s should be written to these bits.7 PINCAP7 SPI0_SOMI/I2C0_SDA pin state captured on rising edge of RESET pin.6 PINCAP6 SPI0_SIMO pin state captured on rising edge of RESET pin.5 PINCAP5 SPI0_CLK/I2C0_SCL pin state captured on rising edge of RESET pin.4 PINCAP4 SPI0_SCS/I2C1_SCL pin state captured on rising edge of RESET pin.3 PINCAP3 SPI0_ENA/I2C1_SDA pin state captured on rising edge of RESET pin.2 PINCAP2 AXR0[8]/AXR1[5]/SPI1_SOMI pin state captured on rising edge of RESET pin.1 PINCAP1 AXR0[9]/AXR1[4]/SPI1_SIMO pin state captured on rising edge of RESET pin.0 PINCAP0 AXR0[7]/SPI1_CLK pin state captured on rising edge of RESET pin.
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Figure 2-7 shows the bit layout of the CFGPIN1 register and Table 2-11 contains a description of the bits.31 8Reserved
76543210
PINCAP15 PINCAP14 PINCAP13 PINCAP12 PINCAP11 PINCAP10 PINCAP9 PINCAP8
LEGEND: R/W = Read/Write; R = Read only; - n= value after reset
Figure 2-7. CFGPIN1 Register Bit Layout (0x4000 0004)
Table 2-11. CFGPIN1 Register Bit Field Description (0x4000 0004)
BIT NO. NAME DESCRIPTION
31:8 Reserved Reads are indeterminate. Only 0s should be written to these bits.7 PINCAP15 AXR0[5]/ SPI1_SCS pin state captured on rising edge of RESET pin.6 PINCAP14 AXR0[6]/ SPI1_ENA pin state captured on rising edge of RESET pin.5 PINCAP13 UHPI_HCS pin state captured on rising edge of RESET pin.4 PINCAP12 UHPI_HD[0] pin state captured on rising edge of RESET pin.3 PINCAP11 EM_D[16]/UHPI_HA[0] pin state captured on rising edge of RESET pin.2 PINCAP10 AFSX0 pin state captured on rising edge of RESET pin.1 PINCAP9 AFSR0 pin state captured on rising edge of RESET pin.0 PINCAP8 AXR0[0] pin state captured on rising edge of RESET pin.
Device Overview18 Submit Documentation Feedback
2.9 Pin Assignments
2.9.1 Pin Maps
SPI0_ENA
/I2C1_
SDA
SPI0_CLK
/I2C0_
SCL
DVDD
VSS
EM_RW
EM_RAS
VSS
EM_BA[1]
EM_A[0]
VSS
EM_A[3]
EM_A[5]
EM_A[7]
EM_A[9]
DVDD
VSS
DVDD
EM_WE_
DQM[3]
EM_A[11]
EM_A[8]
EM_A[6]
EM_A[4]
EM_A[2]
EM_A[1]
EM_A[10]
EM_BA[0]
EM_CS[0]
EM_CS[2]
EM_OE
/I2C1_
SPI0_SCS
SCL
SIMO
SPI0_
DVDD
AXR0[0]
SPI0_
SOMI
/I2C0_
SDA
AHCLKR2
EM_WAIT
UHPI_
HD[8]
HD[9]
UHPI_
HD[11]
UHPI_
HD[13]
UHPI_
DVDD
HD[1]
UHPI_
UHPI_
HD[4]
HD[2]
UHPI_
HD[6]
UHPI_
HD[7]
UHPI_
EM_CLK
EM_CKE
DQM[1]
EM_WE_
EM_D[8]
DQM[2]
EM_WE_
HD[5]
UHPI_
DVDD
HD[3]
UHPI_
HD[0]
UHPI_
UHPI_
HD[15]
UHPI_
HD[14]
HD[12]
UHPI_
HD[10]
UHPI_
DVDD
DVDD
ACLKR2
AXR0[1]
AXR0[2]AXR0[4]
AXR0[3]
AFSR2
DVDD
VSS
VSS
CVDD
CVDD
CVDD
CVDD
VSS
VSS
DVDD
EM_A[12]
EM_D[10]
EM_D[9]EM_D[11]
EM_D[12]
EM_D[24]
/UHPI_
HA[8]
HA[9]
EM_D[25]
/UHPI_
CVDD
VSS
VSS
VSS
VSS
VSS
VSS
CVDD
ACLKX2
AFSX2
/SPI1_
AXR0[5]
SCS
AXR0[6]
/SPI1_
ENA
VSS
AXR0[7]
/SPI1_
CLK
HCNTL[1]
UHPI_
HINT
AMUTE2/
CVDD
VSS
VSS
VSS
VSS
VSS
VSS
CVDD
/UHPI_
HA[11]
EM_D[27]
HA[10]
EM_D[26]
/UHPI_
EM_D[13]
VSS
EM_D[14]
EM_D[1]
EM_D[0]
EM_D[15]
DVDD HA[12]
EM_D[28]
/UHPI_
HA[13]
EM_D[29]
/UHPI_
VSS
VSS
VSS
VSS
VSS
CVDD
VSS
CVDD
/UHPI_
HA[14]
EM_D[30]
VSS
CVDD
CVDD
VSS
CVDD
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
VSS
CVDD
VSS
CVDD
VSS
CVDD
VSS
VSS
VSS
CVDD
CVDD
CVDD
CVDD
VSS
VSS
DVDD
DVDD
DVDD
DVDD
DVDD
VSS
EM_D[2]
HA[0]
EM_D[16]
/UHPI_
HA[15]
EM_D[31]
/UHPI_
EM_D[3]
EM_D[4]
HA[1]
EM_D[17]
/UHPI_
HA[2]
EM_D[18]
/UHPI_
EM_D[5]
EM_D[6]
HA[3]
EM_D[19]
/UHPI_
EM_D[7]
EM_WE_
DQM[0]
HA[4]
EM_D[20]
/UHPI_
HA[6]
EM_D[22]
/UHPI_
HD[29]
UHPI_
TRST
OSCVDD
HD[31]
UHPI_
HD[18]
UHPI_
UHPI_
HD[20]
HRDY
UHPI_
HDS[1]
UHPI_
HRW
UHPI_
HCNTL[0]
UHPI_
HBE[2]
UHPI_
HBE[1]
UHPI_
HBE[0]
UHPI_
HDS[2]
UHPI_
HCS
UHPI_
HAS
UHPI_
AXR0[8]
/AXR1[5]
/SPI1_
SOMI
SIMO
/SPI1_
/AXR1[4]
AXR0[9]
/AXR1[3]
AXR0[10]
/AXR1[2]
AXR0[11]
/AXR1[1]
AXR0[12]
VSS
/AXR2[1]
AXR0[14]
/AXR1[0]
AXR0[13]
/AXR2[0]
AXR0[15]
ACLKR0
AFSR0
ACLKX0
EM_WE
EM_CAS
HA[5]
EM_D[21]
/UHPI_
HD[26]
UHPI_
HD[27]
UHPI_
HD[28]
UHPI_
TMS
OSCOUT
VSS
UHPI_
HD[17]
HD[19]
UHPI_
HD[21]
UHPI_
HD[22]
UHPI_
HD[23]
UHPI_
/AHCLKR1
AHCLKR0
AFSX0
DVDD
DVDD
DVDD
VSS
VSS
DVDD
HBE[3]
UHPI_
/AHCLKX2
AHCLKX0
AMUTE1
ACLKX1
AFSX1
RESET
CLKIN
OSCIN
PLLHV
HD[30]
UHPI_
TDO
HD[25]
UHPI_
HD[24]
UHPI_
HA[7]
EM_D[23]
/UHPI_
TCK
EMU[1]
EMU[0]
TDI
VSS
OSCVSS
HD[16]
/HHWIL
UHPI_
VSS
AFSR1
ACLKR1
AHCLKX1
AMUTE0
T
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
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Figure 2-8 and Figure 2-9 show the pin assignments on the 256-terminal GDH/ZDH package and the144-pin RFP package, respectively.
Figure 2-8. 256-Terminal Ball Grid Array (GDH/ZDH Suffix)—Bottom View
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78 EM_A[7]
109
1108
72
2 107
3 106
4 105
5 104
6 103
7 102
8 101
9 100
10 99
11 98
12 97
13 96
14 95
15 94
16 93
17 92
18 91
19 90
20 89
21 88
22 87
23 86
24 85
25 84
26 83
27 82
28 81
29 80
30 79
31
32 77
33 76
34 75
35 74
36 73
110 71
111 70
112 69
113 68
114 67
115 66
116 65
117 64
118 63
119 62
120 61
121 60
122 59
123 58
124 57
125 56
126 55
127 54
128 53
129 52
130 51
131 50
132 49
133 48
134 47
135 46
136 45
137 44
138 43
139 42
140 41
141 40
142 39
143 38
37144
VSS
AHCLKX0/AHCLKX2
AMUTE0
AMUTE1
AHCLKX1
VSS
ACLKX1
CVDD
ACLKR1
DVDD
AFSX1
AFSR1
VSS
RESET
VSS
CVDD
CLKIN
VSS
TMS
CVDD
TRST
OSCVSS
OSCIN
OSCOUT
OSCVDD
VSS
PLLHV
TDI
TDO
VSS
DVDD
EMU[0]
CVDD
EMU[1]
TCK
VSS
SPI0_CLK/I2C0_SCL
SPI0_SCS/I2C1_SCL
VSS
SPI0_ENA/I2C1_SDA
EM_OE
DVDD
EM_RW
CVDD
EM_CS[2]
VSS
EM_RAS
EM_CS[0]
EM_BA[0]
VSS
EM_BA[1]
EM_A[10]
DVDD
EM_A[0]
CVDD
EM_A[1]
EM_A[2]
VSS
EM_A[3]
CVDD
EM_A[4]
EM_A[5]
VSS
DVDD
EM_A[6]
VSS
CVDD
EM_A[8]
EM_A[9]
EM_A[11]
DVDD
VSS
SPI0_SIMO
SPI0_SOMI/I2C0_SDA
DVDD
AXR0[0]
VSS
AXR0[1]
AXR0[2]
AXR0[3]
VSS
AXR0[4]
AXR0[5]/SPI1_SCS
AXR0[6]/SPI1_ENA
AXR0[7]/SPI1_CLK
CVDD
VSS
DVDD
AXR0[8]/AXR1[5]/SPI1_SOMI
AXR0[9]/AXR1[4]/SPI1_SIMO
CVDD
VSS
AXR0[10]/AXR1[3]
AXR0[11]/AXR1[2]
CVDD
VSS
AXR0[12]/AXR1[1]
AXR0[13]/AXR1[0]
DVDD
AXR0[14]/AXR2[1]
AXR0[15]/AXR2[0]
ACLKR0
VSS
AFSR0
ACLKX0
AHCLKR0/AHCLKR1
AFSX0
VSS
EM_CLK
EM_CKE
VSS
DVDD
EM_WE_DQM[1]
EM_D[8]
CVDD
EM_D[9]
EM_D[10]
VSS
EM_D[11]
DVDD
EM_D[12]
EM_D[13]
CVDD
EM_D[14]
EM_D[15]
VSS
CVDD
EM_D[0]
EM_D[1]
DVDD
EM_D[2]
EM_D[3]
VSS
EM_D[4]
EM_D[5]
CVDD
EM_D[6]
DVDD
EM_D[7]
VSS
EM_WE_DQM[0]
EM_WE
EM_CAS
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A. Actual size of Thermal Pad is 5.4 mm נ5.4 mm. See Section 7.3 .
Figure 2-9. 144-Pin Low-Profile Quad Flatpack (RFP Suffix)—Top View
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2.9.2 Terminal Functions
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Table 2-12 , the Terminal Functions table, identifies the external signal names, the associated pin/ballnumbers along with the mechanical package designator, the pin type (I, O, IO, OZ, or PWR), whether thepin/ball has any internal pullup/pulldown resistors, whether the pin/ball is configurable as an IO in GPIOmode, and a functional pin description.
Table 2-12. Terminal Functions
GDH/SIGNAL NAME RFP TYPE
(1)
PULL
(2)
GPIO
(3)
DESCRIPTIONZDH
External Memory Interface (EMIF) Address and Control
EM_A[0] 91 J16 O - NEM_A[1] 89 J15 O - NEM_A[2] 88 K15 O - NEM_A[3] 86 L16 O - NEM_A[4] 84 L15 O - NEM_A[5] 83 M16 O - NEM_A[6] 80 M15 O - N EMIF Address BusEM_A[7] 79 N16 O - NEM_A[8] 76 N15 O - NEM_A[9] 75 P16 O - NEM_A[10] 93 H15 O - NEM_A[11] 74 P15 O - NEM_A[12] - P12 O IPD NEM_BA[0] 96 G15 O - N
SDRAM Bank Address and Asynchronous MemoryLow-Order AddressEM_BA[1] 94 H16 O - NEM_CS[0] 97 F15 O - N SDRAM Chip SelectEM_CS[2] 100 E15 O - N Asynchronous Memory Chip SelectEM_CAS 37 R3 O - N SDRAM Column Address StrobeEM_RAS 98 F16 O - N SDRAM Row Address StrobeEM_WE 38 T3 O - N SDRAM/Asynchronous Write EnableEM_CKE 71 T14 O - N SDRAM Clock EnableEM_CLK 70 R14 O - N EMIF Output ClockEM_ WE_DQM[0] 39 R4 O - N Write Enable or Byte Enable for EM_D[7:0]EM_ WE_DQM[1] 67 T13 O - N Write Enable or Byte Enable for EM_D[15:8]EM_ WE_DQM[2] - P13 O IPU N Write Enable or Byte Enable for EM_D[23:16]EM_ WE_DQM[3] - R15 O IPU N Write Enable or Byte Enable for EM_D[31:24]EM_OE 104 D15 O - N SDRAM/Asynchronous Output EnableEM_R W 102 E16 O - N Asynchronous Memory Read/not WriteAsynchronous Wait Input ( Programmable Polarity) orEM_WAIT - D14 I IPU N
Interrupt ( NAND)
(1) TYPE column refers to pin direction in functional mode. If a pin has more than one function with different directions, the functions areseparated with a slash (/).(2) PULL column:
IPD = Internal Pulldown resistorIPU = Internal Pullup resistor(3) If the GPIO column is 'Y', then in GPIO mode, the pin is configurable as an IO unless otherwise marked.
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Table 2-12. Terminal Functions (continued)
GDH/SIGNAL NAME RFP TYPE
(1)
PULL
(2)
GPIO
(3)
DESCRIPTIONZDH
External Memory Interface (EMIF) Data Bus / Universal Host-Port Interface (UHPI) Address Bus Option
EM_D[0] 52 T8 IO - NEM_D[1] 51 R8 IO - NEM_D[2] 49 R7 IO - NEM_D[3] 48 T6 IO - NEM_D[4] 46 R6 IO - NEM_D[5] 45 T5 IO - NEM_D[6] 43 R5 IO - NEM_D[7] 41 T4 IO - N
EMIF Data Bus [Lower 16 Bits]EM_D[8] 66 R13 IO - NEM_D[9] 64 T12 IO - NEM_D[10] 63 R12 IO - NEM_D[11] 61 T11 IO - NEM_D[12] 59 R11 IO - NEM_D[13] 58 R10 IO - NEM_D[14] 56 T9 IO - NEM_D[15] 55 R9 IO - NEM_D[16]/UHPI_HA[0] - N7 IO/I IPD NEM_D[17]/UHPI_HA[1] - P6 IO/I IPD NEM_D[18]/UHPI_HA[2] - N6 IO/I IPD NEM_D[19]/UHPI_HA[3] - P5 IO/I IPD NEM_D[20]/UHPI_HA[4] - P4 IO/I IPD NEM_D[21]/UHPI_HA[5] - P3 IO/I IPD NEM_D[22]/UHPI_HA[6] - N4 IO/I IPD NEM_D[23]/UHPI_HA[7] - R2 IO/I IPD N
EMIF Data Bus [Upper 16 Bits (IO)] orUHPI Address Input (I)EM_D[24]/UHPI_HA[8] - P11 IO/I IPD NEM_D[25]/UHPI_HA[9] - N11 IO/I IPD NEM_D[26]/UHPI_HA[10] - P10 IO/I IPD NEM_D[27]/UHPI_HA[11] - N10 IO/I IPD NEM_D[28]/UHPI_HA[12] - P9 IO/I IPD NEM_D[29]/UHPI_HA[13] - N9 IO/I IPD NEM_D[30]/UHPI_HA[14] - N8 IO/I IPD NEM_D[31]/UHPI_HA[15] - P7 IO/I IPD N
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Table 2-12. Terminal Functions (continued)
GDH/SIGNAL NAME RFP TYPE
(1)
PULL
(2)
GPIO
(3)
DESCRIPTIONZDH
Universal Host-Port Interface (UHPI) Data and Control
UHPI_HD[0] - K13 IO IPD YUHPI_HD[1] - K14 IO IPD YUHPI_HD[2] - M14 IO IPD YUHPI_HD[3] - L13 IO IPD YUHPI_HD[4] - L14 IO IPD YUHPI_HD[5] - N13 IO IPD YUHPI_HD[6] - N14 IO IPD YUHPI_HD[7] - P14 IO IPD Y
UHPI Data Bus [Lower 16 Bits]UHPI_HD[8] - E14 IO IPD YUHPI_HD[9] - F14 IO IPD YUHPI_HD[10] - F13 IO IPD YUHPI_HD[11] - G14 IO IPD YUHPI_HD[12] - G13 IO IPD YUHPI_HD[13] - H14 IO IPD YUHPI_HD[14] - H13 IO IPD YUHPI_HD[15] - J13 IO IPD YUHPI_HD[16]/HHWIL - H1 IO/I IPD YUHPI_HD[17] - G3 IO IPD YUHPI_HD[18] - G4 IO IPD YUHPI_HD[19] - F3 IO IPD YUHPI_HD[20] - F4 IO IPD Y
UHPI Data Bus [Upper 16 Bits (IO)] in the followingmodes:UHPI_HD[21] - E3 IO IPD Y
Fullword Multiplexed Address and DataUHPI_HD[22] - D3 IO IPD Y
Fullword Non-MultiplexedUHPI_HD[23] - C3 IO IPD Y
UHPI_HHWIL (I) on pin UHPI_HD[16]/HHWIL and GPIOUHPI_HD[24] - P2 IO IPD Y
on other pins in the following mode:UHPI_HD[25] - N2 IO IPD Y
Half-word Multiplexed Address and DataUHPI_HD[26] - N3 IO IPD Y
In this mode, UHPI_HHWIL indicates whether the high orlow half-word is being addressed.UHPI_HD[27] - M3 IO IPD YUHPI_HD[28] - L3 IO IPD YUHPI_HD[29] - L4 IO IPD YUHPI_HD[30] - L2 IO IPD YUHPI_HD[31] - H4 IO IPD Y
Universal Host-Port Interface (UHPI) Control
UHPI_HBE[0] - C6 I IPD Y UHPI Byte Enable for UHPI_HD[7:0]UHPI_HBE[1] - C5 I IPD Y UHPI Byte Enable for UHPI_HD[15:8]UHPI_HBE[2] - C4 I IPD Y UHPI Byte Enable for UHPI_HD[23:16]UHPI_HBE[3] - B2 I IPD Y UHPI Byte Enable for UHPI_HD[31:24]UHPI_HCNTL[0] - D9 I IPD Y
UHPI Control Inputs Select Access ModeUHPI_HCNTL[1] - C10 I IPD Y
UHPI Host Address Strobe for Hosts with MultiplexedUHPI_HAS - C9 I IPD Y
Address/Data busUHPI_HR W - D8 I IPD Y UHPI Read/not Write InputUHPI_HDS[1] - D7 I IPU Y
UHPI Select Signals which create the internal HSTROBEactive when:UHPI_HDS[2] - C7 I IPU Y
( UHPI_HCS == '0') & ( UHPI_HDS[1] != UHPI_HDS[2])UHPI_HCS - C8 I IPU YUHPI_HRDY - D6 O IPD Y UHPI Ready Output
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Table 2-12. Terminal Functions (continued)
GDH/SIGNAL NAME RFP TYPE
(1)
PULL
(2)
GPIO
(3)
DESCRIPTIONZDH
McASP0, McASP1, McASP2, and SPI1 Serial Ports
(4)
AHCLKR0/AHCLKR1 143 B3 IO - Y McASP0 and McASP1 Receive Master ClockACLKR0 139 A5 IO - Y McASP0 Receive Bit ClockAFSR0 141 B4 IO - Y McASP0 Receive Frame Sync (L/R Clock)AHCLKX0/AHCLKX2 2 C2 IO - Y McASP0 and McASP2 Transmit Master Clock
(4)
ACLKX0 142 A4 IO - Y McASP0 Transmit Bit ClockAFSX0 144 A3 IO - Y McASP0 Transmit Frame Sync (L/R Clock)AMUTE0 3 C1 O - Y McASP0 MUTE OutputAXR0[0] 113 A14 IO - Y McASP0 Serial Data 0AXR0[1] 115 B13 IO - Y McASP0 Serial Data 1AXR0[2] 116 A13 IO - Y McASP0 Serial Data 2AXR0[3] 117 B12 IO - Y McASP0 Serial Data 3AXR0[4] 119 A12 IO - Y McASP0 Serial Data 4AXR0[5]/ SPI1_SCS 120 B11 IO - Y McASP0 Serial Data 5 or SPI1 Slave Chip SelectAXR0[6]/ SPI1_ENA 121 A11 IO - Y McASP0 Serial Data 6 or SPI1 Enable (Ready)AXR0[7]/SPI1_CLK 122 B10 IO - Y McASP0 Serial Data 7 or SPI1 Serial ClockAXR0[8]/AXR1[5]/ McASP0 Serial Data 8 or McASP1 Serial Data 5 or SPI1126 B9 IO - YSPI1_SOMI Data Pin Slave Out Master InAXR0[9]/AXR1[4]/ McASP0 Serial Data 9 or McASP1 Serial Data 4 or SPI1127 A9 IO - YSPI1_SIMO Data Pin Slave In Master OutAXR0[10]/AXR1[3] 130 B8 IO - Y McASP0 Serial Data 10 or McASP1 Serial Data 3AXR0[11]/AXR1[2] 131 A8 IO - Y McASP0 Serial Data 11 or McASP1 Serial Data 2AXR0[12]/AXR1[1] 134 B7 IO - Y McASP0 Serial Data 12 or McASP1 Serial Data 1AXR0[13]/AXR1[0] 135 B6 IO - Y McASP0 Serial Data 13 or McASP1 Serial Data 0AXR0[14]/AXR2[1] 137 A6 IO - Y McASP0 Serial Data 14 or McASP2 Serial Data 1
(4)
AXR0[15]/AXR2[0] 138 B5 IO - Y McASP0 Serial Data 15 or McASP2 Serial Data 0
(4)
ACLKR1 9 E1 IO - Y McASP1 Receive Bit ClockAFSR1 12 F1 IO - Y McASP1 Receive Frame Sync (L/R Clock)AHCLKX1 5 D1 IO - Y McASP1 Transmit Master ClockACLKX1 7 E2 IO - Y McASP1 Transmit Bit ClockAFSX1 11 F2 IO - Y McASP1 Transmit Frame Sync (L/R Clock)AMUTE1 4 D2 O - Y McASP1 MUTE OutputAHCLKR2 - C14 IO IPD Y McASP2 Receive Master ClockACLKR2 - C13 IO IPD Y McASP2 Receive Bit ClockAFSR2 - C12 IO IPD Y McASP2 Receive Frame Sync (L/R Clock)ACLKX2 - D11 IO IPD Y McASP2 Transmit Bit ClockAFSX2 - C11 IO IPD Y McASP2 Transmit Frame Sync (L/R Clock)AMUTE2/ HINT - D10 O IPD Y McASP2 MUTE Output or UHPI Host Interrupt
SPI0, I2C0, and I2C1 Serial Port Pins
SPI0_SOMI/I2C0_SDA 111 B14 IO - Y SPI0 Data Pin Slave Out Master In or I2C0 Serial DataSPI0_SIMO 110 B15 IO - Y SPI0 Data Pin Slave In Master OutSPI0_CLK/I2C0_SCL 108 C16 IO - Y SPI0 Serial Clock or I2C0 Serial ClockSPI0_SCS/I2C1_SCL 107 C15 IO - Y SPI0 Slave Chip Select or I2C1 Serial ClockSPI0_ENA/I2C1_SDA 105 D16 IO - Y SPI0 Enable (Ready) or I2C1 Serial Data
(4) McASP2 is not available on the C6722B and C6720.
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Table 2-12. Terminal Functions (continued)
GDH/SIGNAL NAME RFP TYPE
(1)
PULL
(2)
GPIO
(3)
DESCRIPTIONZDH
Clocks
OSCIN 23 J2 I - N Oscillator InputOSCOUT 24 J3 O - N Oscillator OutputOSCV
DD
25 J4 PWR - N Oscillator CV
DD
tap point (for filter only)OSCV
SS
22 J1 PWR - N Oscillator V
SS
tap point (for filter only)CLKIN 17 H2 I - N Alternate clock input (3.3-V LVCMOS Input)PLLHV 27 K2 PWR - N PLL 3.3-V Supply Input (requires external filter)
Device Reset
RESET 14 G2 I - N Device reset pin
Emulation/JTAG Port
TCK 35 P1 I IPU N Test ClockTMS 19 K3 I IPU N Test Mode SelectTDI 28 L1 I IPU N Test Data InTDO 29 M2 OZ IPU N Test Data OutTRST 21 K4 I IPD N Test ResetEMU[0] 32 M1 IO IPU N Emulation Pin 0EMU[1] 34 N1 IO IPU N Emulation Pin 1
Power Pins - 256-Terminal GDH/ZDH Package
Core Supply (CV
DD
) E6, E7, E8, E9, E10, E11, G5, G12, H5, H12, J5, J12, K5, K12, M6, M7, M8, M9, M10, M11IO Supply (DV
DD
) A2, A15, B1, B16, D4, D5, D12, D13, E4, E13, J14, M4, M13, N5, N12, P8, R1, R16, T2, T15A1, A7, A10, A16, E5, E12, F5, F6, F7, F8, F9, F10, F11, F12, G1, G6, G7, G8, G9, G10, G11, G16, H3, H6,Ground (V
SS
) H7, H8, H9, H10, H11, J6, J7, J8, J9, J10, J11, K1, K6, K7, K8, K9, K10, K11, K16, L5, L6, L7, L8, L9, L10,L11, L12, M5, M12, T1, T7, T10, T16
Power Pins - 144-Pin RFP Package
Core Supply (CV
DD
) 8, 16, 20, 33, 44, 53, 57, 65, 77, 85, 90, 101, 123, 128, 132IO Supply (DV
DD
) 10, 31, 42, 50, 60, 68, 73, 81, 92, 103, 112, 125, 136Ground (V
SS
) 1, 6, 13, 15, 18, 26, 30, 36, 40, 47, 54, 62, 69, 72, 78, 82, 87, 95, 99, 106, 109, 114, 118, 124, 129, 133, 140
Submit Documentation Feedback Device Overview 25
2.10 Development
2.10.1 Development Support
2.10.2 Device Support
2.10.2.1 Device and Development-Support Tool Nomenclature
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TI offers an extensive line of development tools for the TMS320C6000™ DSP platform, including tools toevaluate the performance of the processors, generate code, develop algorithm implementations, and fullyintegrate and debug software and hardware modules.
The following products support development of C6000™ DSP-based applications:
Software Development Tools:
Code Composer Studio™ Integrated Development Environment (IDE): including Editor
C/C++/Assembly Code Generation, and Debug plus additional development tools
Scalable, Real-Time Foundation Software ( DSP/BIOS™), which provides the basic run-time targetsoftware needed to support any DSP application.
Hardware Development Tools:
Extended Development System ( XDS™) Emulator (supports C6000™ DSP multiprocessor system debug)EVM (Evaluation Module)
For a complete listing of development-support tools for the TMS320C6000™ DSP platform, visit the TexasInstruments web site on the Worldwide Web at http://www.ti.com uniform resource locator (URL). Forinformation on pricing and availability, contact the nearest TI field sales office or authorized distributor.
To designate the stages in the product development cycle, TI assigns prefixes to the part numbers of allDSP devices and support tools. Each DSP commercial family member has one of three prefixes: TMX,TMP, or TMS (e.g., TMS320C6727BZDH275). Texas Instruments recommends two of three possibleprefix designators for its support tools: TMDX and TMDS. These prefixes represent evolutionary stages ofproduct development from engineering prototypes (TMX / TMDX) through fully qualified productiondevices/tools (TMS / TMDS).
Device development evolutionary flow:
TMX Experimental device that is not necessarily representative of the final device’s electricalspecifications
TMP Final silicon die that conforms to the device’s electrical specifications but has not completedquality and reliability verification
TMS Fully-qualified production device
Support tool development evolutionary flow:
TMDX Development support product that has not yet completed Texas Instruments internalqualification testing
TMDS Fully qualified development support product
TMX and TMP devices and TMDX development-support tools are shipped against the followingdisclaimer:
“Developmental product is intended for internal evaluation purposes."
TMS devices and TMDS development-support tools have been characterized fully, and the quality andreliability of the device have been demonstrated fully. TI’s standard warranty applies.
Device Overview26 Submit Documentation Feedback
C672x DSP:
6727B
6726B
6722B
6720
PREFIX DEVICE SPEED RANGE
TMS 320 C6727B GDH 250
TMX= Experimental device
TMP= Prototype device
TMS= Qualified device
DEVICE FAMILY
320 = TMS320t DSP family
PACKAGE TYPE§
GDH = 256-terminal plastic BGA
ZDH = 256-terminal Green plastic BGA
RFP = 144-pin PowerPAD Green TQFP
DEVICE
The extended temperature “A version” devices may have different operating conditions than the commercial temperature devices. For
more details, see the recommended operating conditions portion of this data sheet.
BGA = Ball Grid Array
TQFP = Thin Quad Flatpack
§The ZDH mechanical package designator represents the Green version of the GDH package. For more detailed information, see the
Mechanical Data section of this document.
For actual device part numbers (P/Ns) and ordering information, see the TI website (www.ti.com).
TEMPERATURE RANGE (DEFAULT: 0°C TO 90°C)
A
Blank = 0°C to 90°C, commercial temperature
A = −40°C to 105°C, extended temperature
350 (350-MHz CPU)
300 (300-MHz CPU)
275 (275-MHz CPU)
266 (266-MHz CPU)
250 (250-MHz CPU)
225 (225-MHz CPU)
200 (200-MHz CPU)
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Predictions show that prototype devices (TMX or TMP) have a greater failure rate than the standardproduction devices. Texas Instruments recommends that these devices not be used in any productionsystem because their expected end-use failure rate still is undefined. Only qualified production devices areto be used.
TI device nomenclature also includes a suffix with the device family name. This suffix indicates thepackage type (for example, ZDH), the temperature range (for example, “A” is the extended temperaturerange), and the device speed range in megahertz (for example, -300 is 300 MHz). Figure 2-10 provides alegend for reading the complete device name for any TMS320C6000™ DSP platform member.
The ZDH package, like the GDH package, is a 256-ball plastic BGA, but Green.
For device part numbers and further ordering information for TMS320C672x in the GDH, ZDH, and RFPpackage types, see the Texas Instruments (TI) website at http://www.ti.com or contact your TI salesrepresentative.
Figure 2-10. TMS320C672x DSP Device Nomenclature
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2.10.2.2 Documentation Support
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Extensive documentation supports all TMS320™ DSP family generations of devices from productannouncement through applications development. The types of documentation available include: datamanuals, such as this document, with design specifications; complete user's reference guides for alldevices and tools; technical briefs; development-support tools; on-line help; and hardware and softwareapplications. The following is a brief, descriptive list of support documentation specific to the C672x DSPdevices:
SPRS277 C9230C100 TMS320C672x Floating-Point Digital Signal Processor ROM Data Manual.Describes the features of the C9230C100 TMS320C672x digital signal processor ROM.
SPRZ232 TMS320C6727, TMS320C6727B, TMS320C6726, TMS320C6726B, TMS320C6722,TMS320C6722B, TMS320C6720 Digital Signal Processors Silicon Errata. Describes theknown exceptions to the functional specifications for the TMS320C6727, TMS320C6727B,TMS320C6726, TMS320C6726B, TMS320C6722, TMS320C6722B, and TMS320C6720digital signal processors (DSPs).
SPRU723 TMS320C672x DSP Peripherals Overview Reference Guide. This document provides anoverview and briefly describes the peripherals available on the TMS320C672x digital signalprocessors (DSPs) of the TMS320C6000 DSP platform.
SPRU877 TMS320C672x DSP Inter-Integrated Circuit (I2C) Module Reference Guide. Thisdocument describes the inter-integrated circuit (I2C) module in the TMS320C672x digitalsignal processors (DSPs) of the TMS320C6000 DSP platform.
SPRU795 TMS320C672x DSP Dual Data Movement Accelerator (dMAX) Reference Guide. Thisdocument provides an overview and describes the common operation of the data movementaccelerator (dMAX) controller in the TMS320C672x digital signal processors (DSPs) of theTMS320C6000 DSP platform. This document also describes operations and registers uniqueto the dMAX controller.
SPRAA78 TMS320C6713 to TMS320C672x Migration. This document describes the issues related tomigrating from the TMS320C6713 to TMS320C672x digital signal processor (DSP).
SPRU711 TMS320C672x DSP External Memory Interface (EMIF) User's Guide. This documentdescribes the operation of the external memory interface (EMIF) in the TMS320C672x digitalsignal processors (DSPs) of the TMS320C6000 DSP platform.
SPRU718 TMS320C672x DSP Serial Peripheral Interface (SPI) Reference Guide. This referenceguide provides the specifications for a 16-bit configurable, synchronous serial peripheralinterface. The SPI is a programmable-length shift register, used for high speedcommunication between external peripherals or other DSPs.
SPRU719 TMS320C672x DSP Universal Host Port Interface (UHPI) Reference Guide. Thisdocument provides an overview and describes the common operation of the universal hostport interface (UHPI).
SPRU878 TMS320C672x DSP Multichannel Audio Serial Port (McASP) Reference Guide. Thisdocument describes the multichannel audio serial port (McASP) in the TMS320C672x digitalsignal processors (DSPs) of the TMS320C6000 DSP platform.
SPRU879 TMS320C672x DSP Software-Programmable Phase-Locked Loop (PLL) ControllerReference Guide. This document describes the operation of the software-programmablephase-locked loop (PLL) controller in the TMS320C672x digital signal processors (DSPs) ofthe TMS320C6000 DSP platform.
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SPRU733 TMS320C67x/C67x+ DSP CPU and Instruction Set Reference Guide. Describes the CPUarchitecture, pipeline, instruction set, and interrupts for the TMS320C67x and TMS320C67x+digital signal processors (DSPs) of the TMS320C6000 DSP platform. The C67x/C67x+ DSPgeneration comprises floating-point devices in the C6000 DSP platform. The C67x+ DSP isan enhancement of the C67x DSP with added functionality and an expanded instruction set.
SPRAA69 Using the TMS320C672x Bootloader Application Report. This document describes thedesign details about the TMS320C672x bootloader. This document also addresses parallelflash and HPI boot to the extent relevant.
SPRU301 TMS320C6000 Code Composer Studio Tutorial. This tutorial introduces you to some ofthe key features of Code Composer Studio. Code Composer Studio extends the capabilitiesof the Code Composer Integrated Development Environment (IDE) to include full awarenessof the DSP target by the host and real-time analysis tools. This tutorial assumes that youhave Code Composer Studio, which includes the TMS320C6000 code generation tools alongwith the APIs and plug-ins for both DSP/BIOS and RTDX. This manual also assumes thatyou have installed a target board in your PC containing the DSP device.
SPRU198 TMS320C6000 Programmer's Guide. Reference for programming the TMS320C6000 digitalsignal processors (DSPs). Before you use this manual, you should install your codegeneration and debugging tools. Includes a brief description of the C6000 DSP architectureand code development flow, includes C code examples and discusses optimization methodsfor the C code, describes the structure of assembly code and includes examples anddiscusses optimizations for the assembly code, and describes programming considerationsfor the C64x DSP.
SPRU186 TMS320C6000 Assembly Language Tools v6.0 Beta User's Guide. Describes theassembly language tools (assembler, linker, and other tools used to develop assemblylanguage code), assembler directives, macros, common object file format, and symbolicdebugging directives for the TMS320C6000 platform of devices (including the C64x+ andC67x+ generations). NOTE: The enhancements to tools release v5.3 to support theC672x devices are documented in the tools v6.0 documentation.
SPRU187 TMS320C6000 Optimizing Compiler v6.0 Beta User's Guide. Describes theTMS320C6000 C compiler and the assembly optimizer. This C compiler accepts ANSIstandard C source code and produces assembly language source code for theTMS320C6000 platform of devices (including the C64x+ and C67x+ generations). Theassembly optimizer helps you optimize your assembly code. NOTE: The enhancements totools release v5.3 to support the C672x devices are documented in the tools v6.0documentation.
SPRA839 Using IBIS Models for Timing Analysis. Describes how to properly use IBIS models toattain accurate timing analysis for a given system.
The tools support documentation is electronically available within the Code Composer Studio™ IntegratedDevelopment Environment (IDE). For a complete listing of C6000™ DSP latest documentation, visit theTexas Instruments web site on the Worldwide Web at http://www.ti.com uniform resource locator (URL).
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3 Device Configurations
3.1 Device Configuration Registers
3.2 Peripheral Pin Multiplexing Options
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The C672x DSP includes several device-level configuration registers, which are listed in Table 3-1 . Theseregisters need to be programmed as part of the device initialization procedure. See Section 3.2 .
Table 3-1. Device-Level Configuration Registers
REGISTER NAME BYTE ADDRESS DESCRIPTION DEFINED
CFGPIN0 0x4000 0000 Captures values of eight pins on rising edge of RESET pin. Table 2-10CFGPIN1 0x4000 0004 Captures values of eight pins on rising edge of RESET pin. Table 2-11CFGHPI 0x4000 0008 Controls enable of UHPI and selection of its operating mode. Table 4-14CFGHPIAMSB 0x4000 000C Controls upper byte of UHPI address into C672x address space in Table 4-15Non-Multiplexed Mode or if explicitly enabled for security purposes.CFGHPIAUMB 0x4000 0010 Controls upper middle byte of UHPI address into C672x address space Table 4-16in Non-Multiplexed Mode or if explicitly enabled for security purposes.CFGRTI 0x4000 0014 Selects the sources for the RTI Input Captures from among the six Table 4-39McASP DMA events.CFGMCASP0 0x4000 0018 Selects the peripheral pin to be used as AMUTEIN0. Table 4-21CFGMCASP1 0x4000 001C Selects the peripheral pin to be used as AMUTEIN1. Table 4-22CFGMCASP2
(1)
0x4000 0020 Selects the peripheral pin to be used as AMUTEIN2. Table 4-23CFGBRIDGE 0x4000 0024 Controls reset of the bridge BR2 in Figure 2-4 . This bridge must be reset Table 2-7explicitly after any change to the PLL controller affecting SYSCLK1 andSYSCLK2 and before the dMAX or UHPI accesses the CPU Slave Port(CSP).
(1) CFGMCASP2 is reserved on the C6722B and C6720.
This section describes the options for configuring peripherals which share pins on the C672x DSP.Table 3-2 lists the options for configuring the SPI0, I2C0, and I2C1 peripheral pins.
Table 3-2. Options for Configuring SPI0, I2C0, and I2C1
CONFIGURATION
OPTION 1 OPTION 2 OPTION 3
PERIPHERAL SPI0 3-, 4,- or 5-pin mode 3-pin mode disabledI2C0 disabled disabled enabledI2C1 disabled enabled enabled
PINS SPI0_SOMI/I2C0_SDA SPI0_SOMI SPI0_SOMI I2C0_SDASPI0_SIMO SPI0_SIMO SPI0_SIMO GPIO through SPI0_SIMO pin controlSPI0_CLK/I2C0_SCL SPI0_CLK SPI0_CLK I2C0_SCLSPI0_SCS/I2C1_SCL SPI0_SCS I2C1_SCL I2C1_SCLSPI0_ENA/I2C1_SDA SPI0_ENA I2C1_SDA I2C1_SDA
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Table 3-3 lists the options for configuring the SPI1, McASP0, and McASP1 pins. Note that there areadditional finer grain options when selecting which McASP controls the particular AXR serial data pins butthese options are not listed here and can be made on a pin by pin basis.
Table 3-3. Options for Configuring SPI1, McASP0, and McASP1 Data Pins
CONFIGURATION
OPTION 1 OPTION 2 OPTION 3 OPTION 4 OPTION 5
PERIPHERAL SPI1 5-pin mode 4-pin mode 4-pin mode 3-pin mode disabledMcASP0 11 12 12 13 16(max data pins)McASP1 4 4 4 4 6(max data pins)
PINS AXR0[5]/ SPI1_SCS SPI1_SCS AXR0[5] AXR0[5] AXR0[5]SPI1_SCS
AXR0[6]/ SPI1_ENA AXR0[6] SPI1_ENA AXR0[6] AXR0[6]SPI1_ENA
AXR0[7]/ SPI1_CLK SPI1_CLK SPI1_CLK SPI1_CLK AXR0[7]SPI1_CLK
AXR0[8]/AXR1[5]/ SPI1_SOMI SPI1_SOMI SPI1_SOMI SPI1_SOMI AXR0[8] or AXR1[5]SPI1_SOMI
AXR0[9]/AXR1[4]/ SPI1_SIMO SPI1_SIMO SPI1_SIMO SPI1_SIMO AXR0[9] or AXR1[4]SPI1_SIMO
Table 3-4 lists the options for configuring the shared EMIF and UHPI pins.
Table 3-4. Options for Configuring EMIF and UHPI (C6727B Only)
CONFIGURATION
OPTION 1 OPTION 2
PERIPHERAL UHPI Multiplexed Address/Data Mode, Fullword, or Non-Multiplexed Address/Data ModeHalf-Word FullwordEMIF 32-bit EMIF Data 16-bit EMIF Data
PINS EM_D[31:16]/ EM_D[31:16] UHPI_HA[15:0]UHPI_HA[15:0]
While Section 3.2 describes at a high level the most common pin multiplexing options, the control of pinmultiplexing is largely determined on an individual pin-by-pin basis. Typically, each peripheral that sharesa particular pin has internal control registers to determine the pin function and whether it is an input or anoutput.
The C672x device determines whether a particular pin is an input or output based upon the followingrules:
The pin will be configured as an output if it is configured as an output in any of the peripherals sharingthe pin.It is recommended that only one peripheral configure a given pin as an output. If more than oneperipheral does configure a particular pin as an output, then the output value is controlled by theperipheral with highest priority for that pin. The priorities for each pin are given in Table 3-5 .The value input on the pin is passed to all peripherals sharing the pin for input simultaneously.
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Table 3-5. Priority of Control of Data Output on Multiplexed Pins
PIN FIRST PRIORITY SECOND PRIORITY THIRD PRIORITY
SPI0_SOMI/I2C0_SDA SPI0_SOMI I2C0_SDASPI0_CLK/I2C0_SCL SPI0_CLK I2C0_SCLSPI0_SCS/I2C1_SCL SPI0_SCS I2C1_SCLSPI0_ENA/I2C1_SDA SPI0_ENA I2C1_SDAAXR0[5]/ SPI1_SCS AXR0[5] SPI1_SCSAXR0[6]/ SPI1_ENA AXR0[6] SPI1_ENAAXR0[7]/SPI1_CLK AXR0[7] SPI1_CLKAXR0[8]/AXR1[5]/SPI1_SOMI AXR0[8] AXR1[5] SPI1_SOMIAXR0[9]/AXR1[4]/SPI1_SIMO AXR0[9] AXR1[4] SPI1_SIMOAXR0[10]/AXR1[3] AXR0[10] AXR1[3]AXR0[11]/AXR1[2] AXR0[11] AXR1[2]AXR0[12]/AXR1[1] AXR0[12] AXR1[1]AXR0[13]/AXR1[0] AXR0[13] AXR1[0]AXR0[14]/AXR2[1] AXR0[14] AXR2[1]AXR0[15]/AXR2[0] AXR0[15] AXR2[0]AHCLKR0/AHCLKR1 AHCLKR0 AHCLKR1AHCLKX0/AHCLKX2 AHCLKX0 AHCLKX2AMUTE2/HINT AMUTE2 HINTHD[16]/HHWIL HD[16] HHWILEM_D[31:16]/UHPI_HA[15:0]
(1)
EM_D[31:16] (Disabled if UHPI_HA[15:0] (Input Only)CFGHPI.NMUX=1)
(1) When using the UHPI in non-multiplexed mode, ensure EM_D[31:16] are configured as inputs so that these pins may be used asUHPI_HA[15:0]. To ensure this, you must set the CFGHPI.NMUX bit to a '1' before the EMIF SDRAM initialization completes;otherwise, a drive conflict will occur. [The EMIF bus parking function drives the data bus in between accesses.]
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4 Peripheral and Electrical Specifications
4.1 Electrical Specifications
4.2 Absolute Maximum Ratings
(1) (2)
4.3 Recommended Operating Conditions
(1)
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This section provides the absolute maximum ratings and the recommended operating conditions for theTMS320C672x DSP.
All electrical and switching characteristics in this data manual are valid over the recommended operatingconditions unless otherwise specified.
Over Operating Case Temperature Range (Unless Otherwise Noted)
UNIT
Supply voltage range, CV
DD
, OSCV
DD
(3)
–0.3 to 1.8 VSupply voltage range, DV
DD
, PLLHV –0.3 to 4 VInput Voltage Range All pins except OSCIN –0.3 to DV
DD
+ 0.5
VOSCIN pin –0.3 to CV
DD
+ 0.5Output Voltage Range All pins except OSCOUT –0.3 to DV
DD
+ 0.5
VOSCOUT pin –0.3 to CV
DD
+ 0.5Clamp Current ±20 mAOperating case temperature range T
C
Default 0 to 90
°CA version –40 to 105Storage temperature range, T
stg
–65 to 150 °C
(1) Stresses beyond those listed under "absolute maximum ratings" may cause permanent damage to the device. These are stress ratingsonly, and functional operation of the device at these or any conditions beyond those indicated under "recommended operatingconditions" is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.(2) All voltage values are with referenced to V
SS
unless otherwise specified.(3) If OSCV
DD
and OSCV
SS
pins are used as filter pins for reduced oscillator jitter, they should not be connected to CV
DD
and V
SSexternally.
MIN NOM MAX UNIT
CV
DD
Core Supply Voltage Default 1.14 1.2 1.32 VC6727B-350 1.33 1.40 1.47DV
DD
I/O Supply Voltage 3.13 3.3 3.47 VT
C
Operating Case Temperature Range Default 0 90
°CA version –40 105
(1) All voltage values are with referenced to V
SS
unless otherwise specified.
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4.4 Electrical Characteristics
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Over Operating Case Temperature Range (Unless Otherwise Noted)
PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
V
OH
High Level Output Voltage I
O
= –100 µA DV
DD
0.2 VV
OL
Low Level Output Voltage I
O
= 100 µA 0.2 VI
OH
High-Level Output Current V
O
= 0.8 DV
DD
–8 mAI
OL
Low-Level Output Current V
O
= 0.22 DV
DD
8 mAV
IH
High-Level Input Voltage 2 DV
DD
VV
IL
Low-Level Input Voltage 0 0.8 VV
HYS
Input Hysterisis 0.13 DV
DD
VI
I
, I
OZ
Input Current and Off State Output Pins without pullup or pulldown ±10Current
Pins with internal pullup –50 –170 µAPins with internal pulldown 50 170t
tr
Input Transition Time 25 nsC
I
Input Capacitance 7 pFC
O
Output Capacitance 7 pFI
DD2V
CV
DD
Supply
(1)
GDH/ZDH, CV
DD
= 1.2 V, 658CPU clock = 300 MHz
mARFP, CV
DD
= 1.2 V, 555CPU clock = 250 MHzI
DD3V
DV
DD
Supply
(1)
GDH/ZDH, DV
DD
= 3.3 V, 7632-bit EMIF speed = 100 MHz
mARFP, DV
DD
= 3.3 V, 5816-bit EMIF speed = 100 MHz
(1) Assumes the following conditions: 25 °C case temperature; 60% CPU utilization; EMIF at 50% utilization (100 MHz), 50% writes, (32 bitsfor GDH/ZDH, 16 bits for RFP), 50% bit switching; two 10-MHz SPI at 100% utilization, 50% bit switching.The actual current draw is highly application-dependent. For more details on core and I/O activity, refer to the TMS320C672x PowerConsumption Summary Application Report (literature number SPRAAA4 ).
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4.5 Parameter Information
4.5.1 Parameter Information Device-Specific Information
Transmission Line
4.0 pF 1.85 pF
Z0 = 50
(see note)
Tester Pin Electronics Data Sheet Timing Reference Point
Output
Under
Test
42 3.5 nH
Device Pin
(see note)
4.5.1.1 Signal Transition Levels
Vref = 1.5 V
4.5.1.2 Signal Transition Rates
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A. The data sheet provides timing at the device pin. For output timing analysis, the tester pin electronics and itstransmission line effects must be taken into account. A transmission line with a delay of 2 ns or longer can be used toproduce the desired transmission line effect. The transmission line is intended as a load only. It is not neccessary toadd or subtract the transmission line delay (2 ns or longer) from the data sheet timings.Input requirements in this data sheet are tested with an input slew rate of < 4 Volts per nanosecond (4 V/ns) at thedevice pin.
Figure 4-1. Test Load Circuit for AC Timing Measurements
All input and output timing parameters are referenced to 1.5 V for both "0" and "1" logic levels.
Figure 4-2. Input and Output Voltage Reference Levels for AC Timing Measurements
All rise and fall transition timing parameters are referenced to V
IL
MAX and V
IH
MIN for input clocks,V
OL
MAX and V
OH
MIN for output clocks.
Figure 4-3. Rise and Fall Transition Time Voltage Reference Levels
All timings are tested with an input edge rate of 4 Volts per nanosecond (4 V/ns).
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4.6 Timing Parameter Symbology
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Timing parameter symbols used in the timing requirements and switching characteristics tables arecreated in accordance with JEDEC Standard 100. To shorten the symbols, some of the pin names andother related terminology have been abbreviated as follows:
Lowercase subscripts and their meanings: Letters and symbols and their meanings:a access time H Highc cycle time (period) L Lowd delay time V Validdis disable time Z High impedanceen enable timef fall timeh hold timer rise timesu setup timet transition timev valid timew pulse duration (width)X Unknown, changing, or don't care level
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4.7 Power Supplies
4.7.1 Power-Supply Sequencing
4.7.2 Power-Supply Decoupling
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For more information regarding TI’s power management products and suggested devices to power TIDSPs, visit www.ti.com/dsppower .
This device does not require specific power-up sequencing between the DV
DD
and CV
DD
voltage rails;however, there are some considerations that the system designer should take into account:1. Neither supply should be powered up for an extended period of time (>1 second) while the othersupply is powered down.2. The I/O buffers powered from the DV
DD
rail also require the CV
DD
rail to be powered up in order to becontrolled; therefore, an I/O pin that is supposed to be 3-stated by default may actually drivemomentarily until the CV
DD
rail has powered up. Systems should be evaluated to determine if there isa possibility for contention that needs to be addressed. In most systems where both the DV
DD
andCV
DD
supplies ramp together, as long as CV
DD
tracks DV
DD
closely, any contention is also mitigated bythe fact that the CV
DD
rail would reach its specified operating range well before the DV
DD
rail has fullyramped.
In order to properly decouple the supply planes from system noise, place as many capacitors (caps) aspossible close to the DSP. The core supply caps can be placed in the interior space of the package andthe I/O supply caps can be placed around the exterior space of the package. For the BGA package, it isrecommended that both the core and I/O supply caps be placed on the underside of the PCB. For theTQFP package, it is recommended that the core supply caps be placed on the underside of the PCB andthe I/O supply caps be placed on the top side of the PCB.
Both core and I/O decoupling can be accomplished by alternating small (0.1 µF) low ESR ceramic bypasscaps with medium (0.220 µF) low ESR ceramic bypass caps close to the DSP power pins and addinglarge tantalum or ceramic caps (ranging from 10 µF to 100 µF) further away. Assuming 0603 caps, it isrecommended that at least 6 small, 6 medium, and 4 large caps be used for the core supply and 12 small,12 medium, and 4 large caps be used for the I/O supply.
Any cap selection needs to be evaluated from an electromagnetic radiation (EMI) point-of-view; EMI variesfrom one system design to another so it is expected that engineers alter the decoupling capacitors tominimize radiation. Refer to the High-Speed DSP Systems Design Reference Guide (literature numberSPRU889) for more detailed design information on decoupling techniques.
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4.8 Reset
4.8.1 Reset Electrical Data/Timing
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A hardware reset ( RESET) is required to place the DSP into a known good state out of power-up. TheRESET signal can be asserted (pulled low) prior to ramping the core and I/O voltages or after the coreand I/O voltages have reached their proper operating conditions. As a best practice, RESET should beheld low during power-up. Prior to deasserting RESET (low-to-high transition), the core and I/O voltagesshould be at their proper operating conditions.
Table 4-1 assumes testing over recommended operating conditions.
Table 4-1. Reset Timing Requirements
NO. MIN MAX UNIT
1 t
w(RSTL)
Pulse width, RESET low 100 ns2 t
su(BPV-RSTH)
Setup time, boot pins valid before RESET high 20 ns3 t
h(RSTH-BPV)
Hold time, boot pins valid after RESET high 20 ns
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4.9 Dual Data Movement Accelerator (dMAX)
4.9.1 dMAX Device-Specific Information
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The dMAX is a module designed to perform Data Movement Acceleration. The dMAX controller handlesuser-programmed data transfers between the internal data memory controller and the device peripheralson the C672x DSP. The dMAX allows movement of data to/from any addressable memory space,including internal memory, peripherals, and external memory. The dMAX controller in the C672x DSP hasa different architecture from the previous EDMA controller in the C621x/C671x devices.
The dMAX controller includes features, such as capability to perform three-dimensional data transfers foradvanced data sorting, capability to manage a section of the memory as a circular buffer/FIFO with delaytap based reading and writing data. The dMAX controller is capable of concurrently processing twotransfer requests (provided that they are to/from different source/destinations).
Figure 4-4 shows a block diagram of the dMAX controller.
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Event Entry #0
Event Entry #k
Event Entry #31
Transfer Entry #0
Transfer Entry #k
Transfer Entry #7
Reserved
Event
Entry
Table
Transfer
Entry
Table
HiMAX
RAM
R/W
Control
R/W
HiMAX
(MAX0)
Event
Encoder
+
Event and
Interrupt
Registers
LoMAX
(MAX1)
Transfer
Entry
Table
LoMAX
RAM
R/W
Transfer Entry #7
Transfer Entry #k
Transfer Entry #0
Event Entry #31
Reserved
Event
Table
Entry Event Entry #k
Event Entry #0
High-Priority
REQ
Low-Priority
REQ
High-Priority PaRAM
To/From
Crossbar
Switch
LoMAX
Master
Crossbar
Switch
Port
Events
Interrupt
Lines to
the CPU
HiMAX
Master
Crossbar
Switch
Port
dMAX
Low-Priority PaRAM
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Figure 4-4. dMAX Controller Block Diagram
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The dMAX controller comprises:Event and interrupt processing registersEvent encoderHigh-priority event Parameter RAM (PaRAM)Low-priority event Parameter RAM (PaRAM)Address-generation hardware for High-Priority Events MAX0 (HiMAX)Address-generation hardware for Low-Priority Events MAX1 (LoMAX)
The TMS320C672x Peripheral Bus Structure can be described logically as a Crossbar Switch with fivemaster ports and five slave ports. When accessing the slave ports, the MAX0 (HiMAX) module is alwaysgiven the highest priority followed by the MAX1 (LoMAX) module. In other words, in case several masters(including MAX0 and MAX1) attempt to access same slave port concurrently, the MAX0 will be given thehighest priority followed by MAX1.
Event signals are connected to bits of the dMAX Event Register (DER), and the bits in the DER reflect thecurrent state of the event signals. An event is defined as a transition of the event signal. The dMAX EventFlag Register (DEFR) can be programmed, individually for each event signal, to capture either low-to-highor high-to-low transitions of the bits in the DER (event polarity is individually programmable).
An event is a synchronization signal that can be used: 1) to either trigger dMAX to start a transfer, or 2) togenerate an interrupt to the CPU. All the events are sorted into two groups: low-priority event group andhigh-priority event group.
The High-Priority Data Movement Accelerator MAX0 (HiMAX) module is dedicated to serving requestscoming from the high-priority event group. The Low-Priority Data Movement Accelerator MAX1 (LoMAX)module is dedicated to serving requests coming from the low-priority event group.
Each PaRAM contains two sections: the event entry table section and the transfer entry table section. Anevent entry describes an event type and associates the event to either one of transfer types or to aninterrupt. In case an event entry associates the event to one of the transfer types, the event entry willcontain a pointer to the specific transfer entry in the transfer entry table. The transfer table may contain upto eight transfer entries. A transfer entry specifies details required by the dMAX controller to perform thetransfer. In case an event entry associates the event to an interrupt, the event entry specifies whichinterrupt should be generated to the CPU in case the event arrives.
Prior to enabling events and triggering a transfer, the event entry and transfer entry must be configured.The event entry must specify: type of transfer, transfer details (type of synchronization, reload, elementsize, etc.), and should include a pointer to the transfer entry. The transfer entry must specify: source,destination, counts, and indexes. If an event is sorted in the high-priority event group, the event entry andtransfer entry must be specified in the high-priority Parameter RAM. If an event is sorted in the low-priorityevent group, the event entry and transfer entry must be specified in the low-priority parameter RAM.
The dMAX Event Flag Register (DEFR) captures up to 31 separate events; therefore, it is possible forevents to occur simultaneously on the dMAX event inputs. In such cases, the event encoder resolves theorder of processing. This mechanism sorts simultaneous events and sets the priority of the events. ThedMAX controller can simultaneously process one event from each priority group. Therefore, the twohighest-priority events (one from each group) can be processed at the same time.
An event-triggered dMAX transfer allows the submission of transfer requests to occur automatically basedon system events, without any intervention by the CPU. The dMAX also includes support for CPU-initiatedtransfers for added control and robustness, and they can be used to start memory-to-memory transfers.To generate an event to the dMAX controller the CPU must create a transition on one of the bits from thedMAX Event Trigger (DETR) Register, which are mapped to the DER register.
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Table 4-2 lists how the synchronization events are associated with event numbers in the dMAX controller.
Table 4-2. dMAX Peripheral Event Input Assignments
EVENT NUMBER EVENT ACRONYM EVENT DESCRIPTION
0 DETR[0] The CPU triggers the event by creating appropriate transition (edge) on bit0in DETR register.1 DETR[16] The CPU triggers the event by creating appropriate transition (edge) on bit16in DETR register.2 RTIREQ0 RTI DMA REQ[0]3 RTIREQ1 RTI DMA REQ[1]4 MCASP0TX McASP0 TX DMA REQ5 MCASP0RX McASP0 RX DMA REQ6 MCASP1TX McASP1 TX DMA REQ7 MCASP1RX McASP1 RX DMA REQ8 MCASP2TX McASP2 TX DMA REQ9 MCASP2RX McASP2 RX DMA REQ10 DETR[1] The CPU triggers the event by creating appropriate transition (edge) on bit1in DETR register.11 DETR[17] The CPU triggers the event by creating appropriate transition (edge) on bit17in DETR register.12 UHPIINT UHPI CPU_INT13 SPI0RX SPI0 DMA_RX_REQ14 SPI1RX SPI1 DMA_RX_REQ15 RTIREQ2 RTI DMA REQ[2]16 RTIREQ3 RTI DMA REQ[3]17 DETR[2] The CPU triggers the event by creating appropriate transition (edge) on bit2in DETR register.18 DETR[18] The CPU triggers the event by creating appropriate transition (edge) on bit18in DETR register.19 I2C0XEVT I2C 0 Transmit Event20 I2C0REVT I2C 0 Receive Event21 I2C1XEVT I2C 1 Transmit Event22 I2C1REVT I2C 1 Receive Event23 DETR[3] The CPU triggers the event by creating appropriate transition (edge) on bit3in DETR register.24 DETR[19] The CPU triggers the event by creating appropriate transition (edge) on bit19in DETR register.25 Reserved26 MCASP0ERR AMUTEIN0 or McASP0 TX INT or McASP0 RX INT (error on McASP0)27 MCASP1ERR AMUTEIN1 or McASP1 TX INT or McASP1 RX INT (error on McASP1)28 MCASP2ERR AMUTEIN2 or McASP2 TX INT or McASP2 RX INT (error on McASP2)29 OVLREQ[0/1] Error on RTI30 DETR[20] The CPU triggers the event by creating appropriate transition (edge) on bit20in DETR register.31 DETR[21] The CPU triggers the event by creating appropriate transition (edge) on bit21in DETR register.
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4.9.2 dMAX Peripheral Registers Description(s)
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Table 4-3 is a list of the dMAX registers.
Table 4-3. dMAX Configuration Registers
BYTE ADDRESS REGISTER NAME DESCRIPTION
0x6000 0008 DEPR Event Polarity Register0x6000 000C DEER Event Enable Register0x6000 0010 DEDR Event Disable Register0x6000 0014 DEHPR Event High-priority Register0x6000 0018 DELPR Event Low-priority Register0x6000 001C DEFR Event Flag Register0x6000 0034 DER0 Event Register 00x6000 0054 DER1 Event Register 10x6000 0074 DER2 Event Register 20x6000 0094 DER3 Event Register 30x6000 0040 DFSR0 FIFO Status Register 00x6000 0060 DFSR1 FIFO Status Register 10x6000 0080 DTCR0 Transfer Complete Register 00x6000 00A0 DTCR1 Transfer Complete Register 1N/A DETR Event Trigger Register (Located in C67x+ DSP Register File)N/A DESR Event Status Register (Located in C67x+ DSP Register File)
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4.10 External Interrupts
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The C672x DSP has no dedicated general-purpose interrupt pins, but the dMAX can be used incombination with a McASP AMUTEIN signal to provide external interrupt capability. There is a multiplexerfor each McASP, controlled by the CFGMCASP0/1/2 registers, which allows the AMUTEIN input for thatMcASP to be sourced from one of seven I/O pins on the DSP. Once a pin is configured as an AMUTEINsource, a very short pulse (two SYSCLK2 cycles or more) on that pin will generate an event to the dMAX.This event can trigger the dMAX to generate a CPU interrupt by programming the assoicated Event Entry.
There are a few additional points to consider when using the AMUTEIN signal to enable external interruptsas described above. The I/O pin selected by the CFGMCASP0/1/2 registers must be configured as ageneral-purpose input pin within the associated peripheral. Also, the AMUTEIN signal should be disabledwithin the corresponding McASP so that AMUTE is not driven when AMUTEIN is active. This can be doneby clearing the INEN bit of the AMUTE register inside the McASP. Finally, AMUTEIN events are logicallyORed with the McASP transmit and receive error events within the dMAX; therefore, the ISR thatprocesses the dMAX interrupt generated by these events must discern the source of the event.
The EMIF EM_WAIT pin has the ability to generate an NMI (INT1) based upon a rising edge on theEM_WAIT pin. Note that while this interrupt is connected to the CPU NMI (non-maskable interrupt), it isactually maskable through the EMIF control registers. In fact, the default state for this interrupt is disabled.Also, interrupt generation always occurs on a rising edge of EM_WAIT; the polarity selection for wait stategeneration has no effect on the interrupt polarity. The EM_WAIT pin should remain asserted for at leasttwo SYSCLK3 cycles to ensure that the edge is detected.
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4.11 External Memory Interface (EMIF)
4.11.1 EMIF Device-Specific Information
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The C672x DSP includes an external memory interface (EMIF) for optional SDRAM, NOR FLASH, NANDFLASH, or SRAM. The key features of this EMIF are:One chip select ( EM_CS[0]) dedicated for x16 and x32 SDRAM (x8 not supported)One chip select ( EM_CS[2]) dedicated for x8, x16, or x32 NOR FLASH; x8, x16, or x32 AsynchronousSRAM; or x8 or x16 NAND FLASHData bus width is 16 bits on the C6726B, C6722B, and C6720; and 32 bits on the C6727B.SDRAM burst length of 16 bytesExternal Wait Input on the C6727B through EM_WAIT (programmable active-high or active-low)External Wait pin functions as an interrupt for NAND Flash supportNAND Flash logic calculates ECC on blocks of up to 512 bytesECC logic suitable for single-bit errors
Figure 4-5 and Figure 4-6 show typical examples of EMIF-to-memory hookup on the C672x DSP.
As the figures illustrate, the C672x DSP includes a limited number of EMIF address lines. These aresufficient to connect to SDRAM seamlessly. Asynchronous memory such as FLASH typically will need touse additional GPIO pins to act as upper address lines during device boot up when the FLASH contentsare copied into SDRAM. (Normally, code is executed from SDRAM since SDRAM has faster accesstimes).
Any pins listed with a ‘Y' in the GPIO column of Table 2-12 may be used for this purpose, as long as it canbe assured that they be pulled low at (and after) reset and held low until configured as outputs by theDSP.
Note that EM_BA[1:0] are used as low-order address lines for the asynchronous interface. For example, inFigure 4-5 and Figure 4-6 , the flash memory is not byte-addressable and its A[0] input selects a 16-bitvalue. The corresponding DSP address comes from EM_BA[1]. The remaining address lines from theDSP (EM_A[12:0]) drive a word address into the flash inputs A[13:1].
For a more detailed explanation of the C672x EMIF operation please refer to the documentTMS320C672x External Memory Interface (EMIF) User's Guide (literature number SPRU711).
Submit Documentation Feedback Peripheral and Electrical Specifications 45
EM_CS[0]
EM_CAS
EM_RAS
EM_WE
EM_CLK
EM_CKE
EM_BA[1:0]
EM_A[11:0]
EM_WE_DQM[0]
EM_WE_DQM[1]
EM_D[15:0]
EM_CS[2]
EM_RW
EM_OE
GPIO
(6 Pins)RESET
C6726B/C6722B/C6720
DSP EMIF
CE
CAS
RAS
WE
CLK
CKE
BA[1:0]
A[11:0]
LDQM
UDQM
DQ[15:0]
2M x 16 x 4 Bank
SDRAM
A[18:13]
RY/BY
RESET
OE
WE
CE
DQ[15:0]
512K x 16
A[0]
A[12:1]
FLASH
EM_BA[1]
RESET
Any GPIO-capable pins which
can be pulled down at reset
can be used to control A[18:13]
for FLASH BOOTLOAD
Examples: AHCLKR0, SPI0_SCS/SCL1
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Figure 4-5. C6726B/C6722B/C6720 DSP 16-Bit EMIF Example
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EM_CS[0]
EM_CAS
EM_RAS
EM_WE
EM_CLK
EM_CKE
EM_BA[1:0]
EM_A[12:0]
EM_WE_DQM[0]
EM_WE_DQM[1]
EM_D[15:0]
EM_WE_DQM[2]
GPIO
(5 Pins)
RESET
C6727B
DSP EMIF
CE
CAS
RAS
WE
CLK
CKE
BA[1:0]
A[12:0]
LDQM
UDQM
DQ[15:0]
4M x 16 x 4 Bank
SDRAM
A[18:14]
RY/BY
RESET
OE
WE
CE
DQ[15:0]
512K x 16
A[0]
A[13:1]
FLASH
EM_BA[1]
RESET
Any GPIO-capable pins which
can be pulled down at reset
can be used to control A[18:14]
for FLASH BOOTLOAD
Examples: AHCLKR0, SPI0_SCS/SCL1
EM_WE_DQM[3]
EM_D[31:16]/UHPI_HA[15:0]
EM_CS[2]
EM_RW
EM_OE
EM_WAIT
BA[1:0]
A[12:0]
DQ[15:0]
LDQM
UDQM
4M x 16 x 4 Bank
RAS
CLK
CKE
WE
CAS
CE
SDRAM
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Figure 4-6. C6727B DSP 32-Bit EMIF Example
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4.11.2 EMIF Peripheral Registers Description(s)
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Table 4-4 is a list of the EMIF registers. For more information about these registers, see theTMS320C672x DSP External Memory Interface (EMIF) User's Guide (literature number SPRU711).
Table 4-4. EMIF Registers
BYTE ADDRESS REGISTER NAME DESCRIPTION
0xF000 0004 AWCCR Asynchronous Wait Cycle Configuration Register0xF000 0008 SDCR SDRAM Configuration Register0xF000 000C SDRCR SDRAM Refresh Control Register0xF000 0010 A1CR Asynchronous 1 Configuration Register0xF000 0020 SDTIMR SDRAM Timing Register0xF000 003C SDSRETR SDRAM Self Refresh Exit Timing Register0xF000 0040 EIRR EMIF Interrupt Raw Register0xF000 0044 EIMR EMIF Interrupt Mask Register0xF000 0048 EIMSR EMIF Interrupt Mask Set Register0xF000 004C EIMCR EMIF Interrupt Mask Clear Register0xF000 0060 NANDFCR NAND Flash Control Register0xF000 0064 NANDFSR NAND Flash Status Register0xF000 0070 NANDF1ECC NAND Flash 1 ECC Register
Peripheral and Electrical Specifications48 Submit Documentation Feedback
4.11.3 EMIF Electrical Data/Timing
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Table 4-5 through Table 4-10 assume testing over recommended operating conditions (see Figure 4-7through Figure 4-13 ).
Table 4-5. 100-MHz EMIF SDRAM Interface Timing Requirements
(1)
NO. MIN MAX UNIT
19 t
su(EM_DV-EM_CLKH)
Input setup time, read data valid on D[31:0] before EM_CLK rising 3 ns20 t
h(EM_CLKH-EM_DIV)
Input hold time, read data valid on D[31:0] after EM_CLK rising 1.9 ns
(1) For more information about supported EMIF frequency, see Table 2-1 .
Table 4-6. 100-MHz EMIF SDRAM Interface Switching Characteristics
(1)
NO. PARAMETER MIN MAX UNIT
1 t
c(EM_CLK)
Cycle time, EMIF clock EM_CLK 10 ns2 t
w(EM_CLK)
Pulse width, EMIF clock EM_CLK high or low 3 ns3 t
d(EM_CLKH-EM_CSV)S
Delay time, EM_CLK rising to EM_CS[0] valid 7.7 ns4 t
oh(EM_CLKH-EM_CSIV)S
Output hold time, EM_CLK rising to EM_CS[0] invalid 1.15 ns5 t
d(EM_CLKH-EM_WE-DQMV)S
Delay time, EM_CLK rising to EM_ WE_DQM[3:0] valid 7.7 ns6 t
oh(EM_CLKH-EM_WE-DQMIV)S
Output hold time, EM_CLK rising to EM_ WE_DQM[3:0] invalid 1.15 ns7 t
d(EM_CLKH-EM_AV)S
Delay time, EM_CLK rising to EM_A[12:0] and EM_BA[1:0] valid 7.7 nsOutput hold time, EM_CLK rising to EM_A[12:0] and EM_BA[1:0]8 t
oh(EM_CLKH-EM_AIV)S
1.15 nsinvalid9 t
d(EM_CLKH-EM_DV)S
Delay time, EM_CLK rising to EM_D[31:0] valid 7.7 ns10 t
oh(EM_CLKH-EM_DIV)S
Output hold time, EM_CLK rising to EM_D[31:0] invalid 1.15 ns11 t
d(EM_CLKH-EM_RASV)S
Delay time, EM_CLK rising to EM_RAS valid 7.7 ns12 t
oh(EM_CLKH-EM_RASIV)S
Output hold time, EM_CLK rising to EM_RAS invalid 1.15 ns13 t
d(EM_CLKH-EM_CASV)S
Delay time, EM_CLK rising to EM_CAS valid 7.7 ns14 t
oh(EM_CLKH-EM_CASIV)S
Output hold time, EM_CLK rising to EM_CAS invalid 1.15 ns15 t
d(EM_CLKH-EM_WEV)S
Delay time, EM_CLK rising to EM_WE valid 7.7 ns16 t
oh(EM_CLKH-EM_WEIV)S
Output hold time, EM_CLK rising to EM_WE invalid 1.15 ns17 t
dis(EM_CLKH-EM_DHZ)S
Delay time, EM_CLK rising to EM_D[31:0] 3-stated 7.7 ns18 t
ena(EM_CLKH-EM_DLZ)S
Output hold time, EM_CLK rising to EM_D[31:0] driving 1.15 ns
(1) For more information about supported EMIF frequency, see Table 2-1 .
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Table 4-7. 133-MHz EMIF SDRAM Interface Timing Requirements
(1)
NO. MIN MAX UNIT
19 t
su(EM_DV-EM_CLKH)
Input setup time, read data valid on D[31:0] before EM_CLK rising 0.4 ns20 t
h(EM_CLKH-EM_DIV)
Input hold time, read data valid on D[31:0] after EM_CLK rising 1.9 ns
(1) For more information about supported EMIF frequency, see Table 2-1 .
Table 4-8. 133-MHz EMIF SDRAM Interface Switching Characteristics
(1)
NO. PARAMETER MIN MAX UNIT
1 t
c(EM_CLK)
Cycle time, EMIF clock EM_CLK 7.5 ns2 t
w(EM_CLK)
Pulse width, EMIF clock EM_CLK high or low 2.25 ns3 t
d(EM_CLKH-EM_CSV)S
Delay time, EM_CLK rising to EM_CS[0] valid 5.1 ns4 t
oh(EM_CLKH-EM_CSIV)S
Output hold time, EM_CLK rising to EM_CS[0] invalid 1.15 ns5 t
d(EM_CLKH-EM_WE-DQMV)S
Delay time, EM_CLK rising to EM_ WE_DQM[3:0] valid 5.1 ns6 t
oh(EM_CLKH-EM_WE-DQMIV)S
Output hold time, EM_CLK rising to EM_ WE_DQM[3:0] invalid 1.15 ns7 t
d(EM_CLKH-EM_AV)S
Delay time, EM_CLK rising to EM_A[12:0] and EM_BA[1:0] valid 5.1 nsOutput hold time, EM_CLK rising to EM_A[12:0] and EM_BA[1:0]8 t
oh(EM_CLKH-EM_AIV)S
1.15 nsinvalid9 t
d(EM_CLKH-EM_DV)S
Delay time, EM_CLK rising to EM_D[31:0] valid 5.1 ns10 t
oh(EM_CLKH-EM_DIV)S
Output hold time, EM_CLK rising to EM_D[31:0] invalid 1.15 ns11 t
d(EM_CLKH-EM_RASV)S
Delay time, EM_CLK rising to EM_RAS valid 5.1 ns12 t
oh(EM_CLKH-EM_RASIV)S
Output hold time, EM_CLK rising to EM_RAS invalid 1.15 ns13 t
d(EM_CLKH-EM_CASV)S
Delay time, EM_CLK rising to EM_CAS valid 5.1 ns14 t
oh(EM_CLKH-EM_CASIV)S
Output hold time, EM_CLK rising to EM_CAS invalid 1.15 ns15 t
d(EM_CLKH-EM_WEV)S
Delay time, EM_CLK rising to EM_WE valid 5.1 ns16 t
oh(EM_CLKH-EM_WEIV)S
Output hold time, EM_CLK rising to EM_WE invalid 1.15 ns17 t
dis(EM_CLKH-EM_DHZ)S
Delay time, EM_CLK rising to EM_D[31:0] 3-stated 5.1 ns18 t
ena(EM_CLKH-EM_DLZ)S
Output hold time, EM_CLK rising to EM_D[31:0] driving 1.15 ns
(1) For more information about supported EMIF frequency, see Table 2-1 .
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Table 4-9. EMIF Asynchronous Interface Timing Requirements
(1) (2)
NO. MIN MAX UNIT
Input setup time, read data valid on EM_D[31:0] before EM_CLK28 t
su(EM_DV-EM_CLKH)A
5 nsrising29 t
h(EM_CLKH-EM_DIV)A
Input hold time, read data valid on EM_D[31:0] after EM_CLK rising 2 ns30 t
su(EM_CLKH-EM_WAITV)A
Setup time, EM_WAIT valid before EM_CLK rising edge 5 ns31 t
h(EM_CLKH-EM_WAITIV)A
Hold time, EM_WAIT valid after EM_CLK rising edge 0 ns33 t
w(EM_WAIT)A
Pulse width of EM_WAIT assertion and deassertion 2E + 5 nsDelay from EM_WAIT sampled deasserted on EM_CLK rising to34 t
d(EM_WAITD-HOLD)A
4E
(3)
nsbeginning of HOLD phaseSetup before end of STROBE phase (if no extended wait states are35 t
su(EM_WAITA-HOLD)A
inserted) by which EM_WAIT must be sampled asserted on 4E
(3)
nsEM_CLK rising in order to add extended wait states.
(4)
(1) E = SYSCLK3 (EM_CLK) period.(2) These parameters apply to memories selected by EM_CS[2] in both normal and NAND modes.(3) These parameters specify the number of EM_CLK cycles of latency between EM_WAIT being sampled at the device pin and the EMIFentering the HOLD phase. However, the asynchronous setup (parameter 30) and hold time (parameter 31) around each EM_CLK edgemust also be met in order to ensure the EM_WAIT signal is correctly sampled.(4) In Figure 4-13 , it appears that there are more than 4 EM_CLK cycles encompassed by parameter 35. However, EM_CLK cycles that arepart of the extended wait period should not be counted; the 4 EM_CLK requirement is to the start of where the HOLD phase wouldbegin if there were no extended wait cycles.
Table 4-10. EMIF Asynchronous Interface Switching Characteristics
(1)
NO. PARAMETER MIN MAX UNIT
100-MHz EMIF Frequency 101 t
c(EM_CLK)
Cycle time, EMIF clock EM_CLK ns133-MHz EMIF Frequency 7.52 t
w(EM_CLK)
Pulse width, high or low, EMIF clock EM_CLK 3 ns17 t
dis(EM_CLKH-EM_DHZ)S
Delay time, EM_CLK rising to EM_D[31:0] 3-stated 7.7 ns18 t
ena(EM_CLKH-EM_DLZ)S
Output hold time, EM_CLK rising to EM_D[31:0] driving 1.15 ns21 t
d(EM_CLKH-EM_CS2V)A
Delay time, from EM_CLK rising edge to EM_CS[2] valid 0 8 ns22 t
d(EM_CLKH-EM_WE_DQMV)A
Delay time, EM_CLK rising to EM_ WE_DQM[3:0] valid 0 8 ns23 t
d(EM_CLKH-EM_AV)A
Delay time, EM_CLK rising to EM_A[12:0] and EM_BA[1:0] valid 0 8 ns24 t
d(EM_CLKH-EM_DV)A
Delay time, EM_CLK rising to EM_D[31:0] valid 0 8 ns25 t
d(EM_CLKH-EM_OEV)A
Delay time, EM_CLK rising to EM_OE valid 0 8 ns26 t
d(EM_CLKH-EM_RW)A
Delay time, EM_CLK rising to EM_R W valid 0 8 ns27 t
dis(EM_CLKH-EM_DDIS)A
Delay time, EM_CLK rising to EM_D[31:0] 3-stated 0 8 ns32 t
d(EM_CLKH-EM_WE)A
Delay time, EM_CLK rising to EM_WE valid 0 8 ns
(1) These parameters apply to memories selected by EM_CS[2] in both normal and NAND modes.
Submit Documentation Feedback Peripheral and Electrical Specifications 51
EM_CLK
EM_BA[1:0]
EM_A[12:0]
EM_D[31:0]
1
2 2
4
6
8
8
12
14
16
3
5
7
7
11
13
15
9
BASIC SDRAM
WRITE OPERATION
EM_CS[0]
EM_WE_DQM[3:0]
EM_RAS
EM_CAS
EM_WE
EM_CLK
EM_BA[1:0]
EM_A[12:0]
EM_D[31:0]
1
2 2
4
6
8
8
12
14
19
20
3
5
7
7
11
13
17 18
2 EM_CLK Delay
BASIC SDRAM
READ OPERATION
EM_CS[0]
EM_WE_DQM[3:0]
EM_RAS
EM_CAS
EM_WE
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Figure 4-7. Basic SDRAM Write Operation
Figure 4-8. Basic SDRAM Read Operation
Peripheral and Electrical Specifications52 Submit Documentation Feedback
EM_CLK
EM_BA[1:0]
EM_A[12:0]
EM_D[31:0] READ DATA
SETUP STROBE HOLD TA
21
22
23
23
25 25
21
22
23
23
28 2917
18
ASYNCHRONOUS READ
WE STROBE MODE
ADDRESS
ADDRESS
EM_CS[2]
EM_WE_DQM[3:0]
EM_OE
EM_WE
EM_RW
EM_CLK
EM_BA[1:0]
EM_A[12:0]
EM_D[31:0] READ DATA
SETUP STROBE HOLD TA
22
23
23
25 25
22
23
23
28 29
21 21
17
18
BYTE LANE ENABLES
ADDRESS
ADDRESS
ASYNCHRONOUS READ
SELECT STROBE MODE
EM_CS[2]
EM_WE_DQM[3:0]
EM_OE
EM_WE
EM_RW
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Figure 4-9. Asynchronous Read WE Strobe Mode
Figure 4-10. Asynchronous Read Select Strobe Mode
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EM_CLK
EM_BA[1:0]
EM_A[12:0]
EM_D[31:0]
SETUP STROBE HOLD
21
22
23
23
32 32
21
22
23
23
22
26 26
24 27
ASYNCHRONOUS WRITE
WE STROBE MODE
ADDRESS
ADDRESS
WRITE DATA
22
BYTE WRITE STROBES
EM_CS[2]
EM_WE_DQM[3:0]
EM_OE
EM_WE
EM_RW
EM_CLK
EM_BA[1:0]
EM_A[12:0]
EM_D[31:0]
SETUP STROBE HOLD
22
23
23
32 32
23
23
26 26
24
22
21 21
27
ASYNCHRONOUS WRITE
SELECT STROBE MODE
BYTE LANE ENABLES
ADDRESS
ADDRESS
WRITE DATA
EM_CS[2]
EM_WE_DQM[3:0]
EM_OE
EM_WE
EM_RW
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Figure 4-11. Asynchronous Write WE Strobe Mode
Figure 4-12. Asynchronous Write Select Strobe Mode
Peripheral and Electrical Specifications54 Submit Documentation Feedback
EM_CLK
EM_WAIT ASSERTED DEASSERTED
SETUP HOLDSTROBESTROBE EXTENDED WAIT STATES
34
35
30 31
3333
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Figure 4-13. EM_WAIT Timing Requirements
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4.12 Universal Host-Port Interface (UHPI) [C6727B Only]
4.12.1 UHPI Device-Specific Information
UHPI_HDS[2]
UHPI_HDS[1]
UHPI_HCS
UHPI_HRDY
Internal HSTROBE
Internal HRDY
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The C672x DSP includes a flexible universal host-port interface (UHPI) with more options than thehost-port interface on the C671x DSP.
The UHPI on the C672x DSP supports three major operating modes listed in Table 4-11 .
Table 4-11. UHPI Major Modes on C672x
UHPI MAJOR MODE EXAMPLE FIGURE
Multiplexed Host Address/Data Half-Word (16-Bit) Mode Figure 4-15Multiplexed Host Address/Data Fullword (32-Bit) Mode Figure 4-16Non-Multiplexed Host Address/Data Fullword (32-Bit) Mode Figure 4-17
In all modes, the UHPI uses three select inputs ( UHPI_HCS, UHPI_HDS[2:1]) which are combinedinternally to produce the internal strobe signal HSTROBE. The HSTROBE strobe signal is used in theUHPI to capture incoming address and control signals on its falling edge and write data on its rising edge.The UHPI_HCS signal also gates the deassertion of the UHPI_HRDY signal externally.
Figure 4-14. UHPI Strobe and Ready Interaction
The two HPI control pins UHPI_HCNTL[1:0] determine the type of access that the host will perform. Notethat only two of the four access types are supported in Non-Multiplexed Host Address/Data FullwordMode.
Table 4-12. HPI Access Types Selected by UHPI_HCNTL[1:0]
NON-MULTIPLEXED MULTIPLEXEDUHPI_HCNTL[1:0] DESCRIPTION MULTIPLEXEDHALF-WORD FULLWORD
FULLWORD
00 HPI Control Register (HPIC) Access Y Y Y01 HPI Data Access (HPID) with autoincrementing address Y Y N10 HPI Address Register (HPIA) Access Y Y N11 HPI Data Access (HPID) without autoincrementing Y Y Yaddress
CAUTIONWhen performing a set of HPID with autoincrementing address accesses(UHPI_HCNTL[1:0] = '01'), the set must begin and end at a word-aligned address. Inaddition, all four of the UHPI_HBE[3:0] must be enabled on every access in the set.
CAUTIONThe encoding of UHPI_CNTL[1:0] on the C672x DSP is different from HCNTL[1:0] onthe C671x DSP. Modes 01 and 10 are swapped.
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Figure 4-15 illustrates the Multiplexed Host Address/Data Half-Word Mode hookup between the C672xDSP and an external host microcontroller. In this mode, each 32-bit HPI access is broken up into twohalves. The UHPI_HD[16]/HHWIL pin functions as UHPI_HHWIL which must be '0' during the first half ofaccess and '1' during the second half.
CAUTIONUnless configured as general-purpose I/O in the UHPI module, UHPI_HD[31:17] andUHPI_HD[16]/HHWIL will be driven as outputs along with UHPI_HD[15:0] when the HPIis read, even though only the lower half-word is used to transfer data. This can beespecially problematic for the UHPI_HD[16]/HHWIL pin which should be used as aninput in this mode. Therefore, be sure to configure the upper half of the UHPI_HD busas general-purpose I/O pins. Furthermore, be sure to program the UHPI_HD[16]function as a general-purpose input to avoid a drive conflict with the external hostMCU.
In this mode, as well as the Multiplexed Host Address/Data Fullword mode, the UHPI can be made moresecure by restricting the upper 16 bits of the DSP addresses it can access to what is set in CFGHPIAMSBand CFGHPIAUMB registers. (See Table 4-15 and Table 4-16 ).
The host is responsible for configuring the internal HPIA register whether or not it is being overridden bythe device configuration registers CFGHPIAMSB and CFGHPIAUMB.
After the HPIA register has been set, either a single or a group of autoincrementing accesses to HPIDmay be performed.
The UHPI_HRDY adds wait states to extend the host MCU access until the C672x DSP has completedthe desired operation.
The HINT signal is available for the DSP to interrupt the host MCU. The UHPI also includes an interrupt tothe DSP core from the host as part of the HPIC register.
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EM_D[31:16]/UHPI_HA[15:0]
(A)
UHPI_HCNTL[1:0]
UHPI_HD[15:0]
UHPI_HD[16]/HHWIL
UHPI_HD[31:17]
UHPI_HAS(B)
UHPI_HBE[1:0](C)
UHPI_HRW
UHPI_HDS[2](G)
UHPI_HDS[1](G)
UHPI_HCS
UHPI_HRDY
AMUTE2/HINT
NC or GPIO
NC
A[x:y](D)
D[15:0]
A[1](E)
BE[1:0](F)
R/W
WE(G)
RD(G)
CS
RDY
INTERRUPT
DSP External Host MCU
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A. May be used as EM_D[31:16]B. Optional for hosts supporting multiplexed address and data. Pull up if not used. Low when address is on the bus.C. DSP byte enables UHPI_HBE[3:2] are not required in this mode.D. Two host address lines or host GPIO if address lines are not available.E. A[1], assuming this address increments from 0 to 1 between two successive 16-bit accesses.F. Byte Enables (active during reads and writes). Some processors support a byte-enable mode on their write-enablepins.G. Only required if needed for strobe timing. Not required if CS meets strobe timing requirements. Tie UHPI_HDS[2] andUHPI_HDS[1] opposite. For more information, see Figure 4-14 .
Figure 4-15. UHPI Multiplexed Host Address/Data Half-Word Mode
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EM_D[31:16]/UHPI_HA[15:0]
(A)
UHPI_HCNTL[1:0]
UHPI_HD[15:0]
UHPI_HD[16]/HHWIL
UHPI_HD[31:17]
UHPI_HAS(B)
UHPI_HBE[3:0]
UHPI_HRW
UHPI_HDS[2]
UHPI_HDS[1]
UHPI_HCS
UHPI_HRDY
AMUTE2/HINT
NC
A[x:y](C)
D[15:0]
D[16]
BE[3:0](D)
R/W
WE(E)
RD(E)
CS
RDY
INTERRUPT
DSP External Host MCU
D[31:17]
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Figure 4-16 illustrates the Multiplexed Host Address/Data Fullword Mode hookup between the C672x DSPand an external host microcontroller. In this mode, all 32 bits of UHPI_HD[31:0] are used and the host canaccess HPIA, HPID, and HPIC in a single bus cycle.
A. May be used as EM_D[31:16]B. Optional for hosts supporting multiplexed address and data. Pull up if not used. Low when address is on the bus.C. Two host address lines or host GPIO if address lines are not available.D. Byte Enables (active during reads and writes). Some processors support a byte-enable mode on their write enablepins.E. Only required if needed for strobe timing. Not required if CS meets strobe timing requirements.
Figure 4-16. UHPI Multiplexed Host Address/Data Fullword Mode
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EM_D[31:16]/UHPI_HA[15:0]
UHPI_HCNTL[1:0]
UHPI_HD[15:0]
UHPI_HD[16]/HHWIL
UHPI_HD[31:17]
UHPI_HAS(B)
UHPI_HBE[3:0]
UHPI_HRW
UHPI_HDS[2]
UHPI_HDS[1]
UHPI_HCS
UHPI_HRDY
AMUTE2/HINT
A[x:y](A)
D[15:0]
D[16]
BE[3:0](C)
R/W
WE(D)
RD(D)
CS
RDY
INTERRUPT
DSP External Host MCU
D[31:17]
A[17:2]
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Figure 4-17 illustrates the Non-Multiplexed Host Address/Data Fullword mode of the UHPI. In this mode,the UHPI behaves almost like an asynchronous SRAM except it asserts the UHPI_HRDY signal. Thismode allows the host to randomly access a 64K-byte page in the C672x address space. The upper 32 bitsof the C672x address are set by the DSP (only) through the CFGHPIAMSB and CFGHPIAUMB registers(see Table 4-15 and Table 4-16 ).
A. Two host address lines or host GPIO if address lines are not available.B. Not used in this mode.C. Byte Enables (active during reads and writes). Some processors support a byte-enable mode on their write enablepins.D. Only required if needed for strobe timing. Not required if CS meets strobe timing requirements.
Figure 4-17. UHPI Non-Multiplexed Host Address/Data Fullword Mode
CAUTIONThe EMIF data bus and UHPI HA inputs share the EM_D[31:16]/UHPI_HA[15:0] pins.When using Non-Multiplexed mode, make sure the EMIF does not drive EM_D[31:16];otherwise, a drive conflict with the external host MCU may result. Normally, the EMIFwill begin to drive the EM_D[31:16] lines immediately after it completes the SDRAMinitialization sequence, which occurs automatically after RESET is released. To avoida drive conflict then, the boot software must set CFGHPI.NMUX to '1' before the EMIFdrives EM_D[31:16]. Setting CFGHPI.NMUX to '1' forces these pins to be input pins.
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4.12.2 UHPI Peripheral Registers Description(s)
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Table 4-13 is a list of the UHPI registers.
Table 4-13. UHPI Configuration Registers
BYTE ADDRESS REGISTER NAME DESCRIPTION
Device-Level Configuration Registers Controlling UHPI
0x4000 0008 CFGHPI UHPI Configuration Register0x4000 000C CFGHPIAMSB Most Significant Byte of UHPI Address0x4000 0010 CFGHPIAUMB Upper Middle Byte of UHPI Address
UHPI Internal Registers
0x4300 0000 PID Peripheral ID Register0x4300 0004 PWREMU Power and Emulation Management Register0x4300 0008 GPIOINT General Purpose I/O Interrupt Control Register0x4300 000C GPIOEN General Purpose I/O Enable Register0x4300 0010 GPIODIR1 General Purpose I/O Direction Register 10x4300 0014 GPIODAT1 General Purpose I/O Data Register 10x4300 0018 GPIODIR2 General Purpose I/O Direction Register 20x4300 001C GPIODAT2 General Purpose I/O Data Register 20x4300 0020 GPIODIR3 General Purpose I/O Direction Register 30x4300 0024 GPIODAT3 General Purpose I/O Data Register 30x4300 0028 Reserved Reserved0x4300 002C Reserved Reserved0x4300 0030 HPIC Control Register0x4300 0034 HPIAW Write Address Register0x4300 0038 HPIAR Read Address Register0x4300 003C Reserved Reserved0x4300 0040 Reserved Reserved
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The UHPI has several device-level configuration registers which affect its behavior. Figure 4-18 ,Figure 4-19 , and Figure 4-20 show the bit layout of these registers. Table 4-14 ,Table 4-15 , andTable 4-16 contain a description of the bits in these registers.31 8Reserved
7 543210
Reserved BYTEAD FULL NMUX PAGEM ENAR/W, 0 R/W, 0 R/W, 0 R/W, 0 R/W, 0
LEGEND: R/W = Read/Write; R = Read only; - n= value after reset
Figure 4-18. CFGHPI Register Bit Layout (0x4000 0008)
Table 4-14. CFGHPI Register Bit Field Description (0x4000 0008)
RESET READBIT NO. NAME DESCRIPTIONVALUE WRITE
31:5 Reserved N/A N/A Reads are indeterminate. Only 0s should be written to these bits.4 BYTEAD 0 R/W UHPI Host Address Type0 = Host Address is a word address1 = Host Address is a byte address3 FULL 0 R/W UHPI Multiplexing Mode (when NMUX = 0)0 = Half-Word (16-bit data) Multiplexed Address and Data Mode1 = Fullword (32-bit data) Multiplexed Address and Data Mode2 NMUX 0 R/W UHPI Non-Multiplexed Mode Enable0 = Multiplexed Address and Data Mode1 = Non-Multiplexed Address and Data Mode (utilizes optional UHPI_HA[15:0] pins).Host data bus is 32 bits in Non-Multiplexed mode. Setting this bit prevents the EMIFfrom driving data out or 'parking' the shared EM_D[31:16]/UHPI_HA[15:0] pins.1 PAGEM 0 R/W UHPI Page Mode Enable (Only for Multiplexed Address and Data Mode).0 = Full 32-bit DSP address specified through host port.1 = Only lower 16 bits of DSP address are specified through host port. Upper 16 bitsare restricted to the page selected by CFGHPIAMSB and CFGHPIAUMB registers.0 ENA 0 R/W UHPI Enable
0 = UHPI is disabled1 = UHPI is enabled. Set this bit to '1' only after configuring the other bits in thisregister.
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31 8Reserved
7 0
HPIAMSB
R/W, 0
LEGEND: R/W = Read/Write; R = Read only; - n= value after reset
Figure 4-19. CFGHPIAMSB Register Bit Layout (0x4000 000C)
Table 4-15. CFGHPIAMSB Register Bit Field Description (0x4000 000C)
RESET READBIT NO. NAME DESCRIPTIONVALUE WRITE
31:8 Reserved N/A N/A Reads are indeterminate. Only 0s should be written to these bits.7:0 HPIAMSB 0 R/W UHPI most significant byte of DSP address to access in Non-Multiplexed mode andin Multiplexed Address and Data mode when PAGEM = 1. Sets bits [31:24] of theDSP internal address as accessed through UHPI.
31 8Reserved
7 0
HPIAUMB
R/W, 0
LEGEND: R/W = Read/Write; R = Read only; - n= value after reset
Figure 4-20. CFGHPIAUMB Register Bit Layout (0x4000 0010)
Table 4-16. CFGHPIAUMB Register Bit Field Description (0x4000 0010)
RESET READBIT NO. NAME DESCRIPTIONVALUE WRITE
31:8 Reserved N/A N/A Reads are indeterminate. Only 0s should be written to these bits.7:0 HPIAUMB 0 R/W UHPI upper middle byte of DSP address to access in Non-Multiplexed mode and inMultiplexed Address and Data mode when PAGEM = 1. Sets bits [23:16] of the DSPinternal address as accessed through UHPI.
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4.12.3 UHPI Electrical Data/Timing
4.12.3.1 Universal Host-Port Interface (UHPI) Read and Write Timing
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Table 4-17 and Table 4-18 assume testing over recommended operating conditions (see Figure 4-21through Figure 4-24 ).
Table 4-17. UHPI Read and Write Timing Requirements
(1) (2)
NO. MIN MAX UNIT
9 t
su(HASL-DSL)
Setup time, UHPI_HAS low before DS falling edge 5 ns10 t
h(DSL-HASL)
Hold time, UHPI_HAS low after DS falling edge 2 ns11 t
su(HAD-HASL)
Setup time, HAD valid before UHPI_HAS falling edge 5 ns12 t
h(HASL-HAD)
Hold time, HAD valid after UHPI_HAS falling edge 5 ns13 t
w(DSL)
Pulse duration, DS low 15 ns14 t
w(DSH)
Pulse duration, DS high 2P ns15 t
su(HAD-DSL)
Setup time, HAD valid before DS falling edge 5 ns16 t
h(DSL-HAD)
Hold time, HAD valid after DS falling edge 5 ns17 t
su(HD-DSH)
Setup time, HD valid before DS rising edge 5 ns18 t
h(DSH-HD)
Hold time, HD valid after DS rising edge 0 ns37 t
su(HCSL-DSL)
Setup time, UHPI_HCS low before DS falling edge 0 ns38 t
h(HRDYL-DSH)
Hold time, DS high after UHPI_HRDY falling edge 1 ns
(1) P = SYSCLK2 period(2) DS refers to HSTROBE. HD refers to UHPI_HD[31:0]. HDS refers to UHPI_HDS[1] or UHPI_HDS[2]. HAD refers to UHPI_HCNTL[0],UHPI_HCNTL[1], UHPI_HHWIL, and UHPI_HR W.
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Table 4-18. UHPI Read and Write Switching Characteristics
(1) (2)
NO. PARAMETER MIN MAX UNIT
Case 1. HPIC or HPIA read 1 15Case 2. HPID read with no
9 * 2H + 20
(3)auto-increment
Case 3. HPID read with1 t
d(DSL-HDV)
Delay time, DS low to HD valid nsauto-increment and read FIFO 9 * 2H + 20
(3)
initially emptyCase 4. HPID read withauto-increment and data previously 1 15prefetched into the read FIFO2 t
dis(DSH-HDV)
Disable time, HD high-impedance from DS high 1 4 ns3 t
en(DSL-HDD)
Enable time, HD driven from DS low 3 15 ns4 t
d(DSL-HRDYH)
Delay time, DS low to UHPI_HRDY high 12 ns5 t
d(DSH-HRDYH)
Delay time, DS high to UHPI_HRDY high 12 nsCase 1. HPID read with no
10 * 2H + 20
(3)auto-incrementDelay time, DS low to UHPI_HRDY6 t
d(DSL-HRDYL)
nsCase 2. HPID read withlow
auto-increment and read FIFO 10 * 2H + 20
(3)
initialy empty7 t
d(HDV-HRDYL)
Delay time, HD valid to UHPI_HRDY low 0 nsCase 1. HPIA write 5 * 2H + 20
(3)
Delay time, DS high to
Case 2. HPID read with34 t
d(DSH-HRDYL)
nsUHPI_HRDY low
auto-increment and read FIFO 5 * 2H + 20
(3)
initially emptyDelay time, DS low to UHPI_HRDY low for HPIA write and FIFO not35 t
d(DSL-HRDYL)
40 * 2H + 20
(3)
nsempty36 t
d(HASL-HRDYH)
Delay time, UHPI_HAS low to UHPI_HRDY high 12 ns
(1) H = 0.5 * SYSCLK2 period(2) DS refers to HSTROBE. HAD refers to UHPI_HCNTL[0], UHPI_HCNTL[1], UHPI_HHWIL, and UHPI_HR W.(3) Max delay is a best case, assuming no delays due to resource conflicts between UHPI and dMAX or CPU. UHPI_HRDY should alwaysbe used to indicate when an access is complete instead of relying on these parameters.
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13 14 13
15 16 15 16
1
32
74
17 18
34
5
UHPI_HCS
UHPI_HDSx
UHPI_HRW
UHPI_HA[15:0]
UHPI_HD[31:0]
(Read)
UHPI_HD[31:0]
(Write)
UHPI_HRDY
Valid Valid
Read data
Write data
Read Write
37 37
6
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A. Depending on the type of write or read operation (HPID or HPIC), transitions on UHPI_HRDY may or may not occur.
Figure 4-21. Non-Multiplexed Read/Write Timings
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UHPI_HCS
UHPI_HAS
UHPI_HRW
UHPI_HHWIL
HSTROBE(A)
UHPI_HD[15:0]
UHPI_HRDY
2
3
1
37 910
14
2
38
12
11
12
11
12
11
13
76
1
3
13
37 910
36
UHPI_HCNTL[1:0]
12
11
12
11
12
11
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A. See Figure 4-14 .B. Depending on the type of write or read operation (HPID without auto-incrementing, HPIA, HPIC, or HPID withauto-incrementing) and the state of the FIFO, transitions on UHPI_HRDY may or may not occur.
Figure 4-22. Multiplexed Read Timings Using UHPI_HAS
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UHPI_HCS
UHPI_HAS
UHPI_HCNTL[1:0]
UHPI_HRW
UHPI_HHWIL
HSTROBE(A)
UHPI_HD[15:0]
UHPI_HRDY
16
15
37
13
14
16
15
37 13
312312
38
7
46
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A. See Figure 4-14 .B. Depending on the type of write or read operation (HPID without auto-incrementing, HPIA, HPIC, or HPID withauto-incrementing) and the state of the FIFO, transitions on UHPI_HRDY may or may not occur.
Figure 4-23. Multiplexed Read Timings With UHPI_HAS Held High
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UHPI_HCS
UHPI_HAS
UHPI_HCNTL[1:0]
UHPI_HRW
UHPI_HHWIL
HSTROBE(A)
UHPI_HD[15:0]
UHPI_HRDY
34
5
17 18
17 18
34
5
438
37
13
16
15 14 13
16
15
37
35
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A. See Figure 4-14 .B. Depending on the type of write or read operation (HPID without auto-incrementing, HPIA, HPIC, or HPID withauto-incrementing) and the state of the FIFO, transitions on UHPI_HRDY may or may not occur.
Figure 4-24. Multiplexed Write Timings With UHPI_HAS Held High
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4.13 Multichannel Audio Serial Ports (McASP0, McASP1, and McASP2)
Receive Logic
Clock/Frame Generator
State Machine
Clock Check and
Serializer 0
Serializer 1
Serializer y
GIO
Control
DIT RAM
384 C
384 U
Optional
Transmit
Formatter
Receive
Formatter
Transmit Logic
Clock/Frame Generator
State Machine
McASPx (x = 0, 1, 2)
Peripheral
Configuration
Bus
McASP
DMA Bus
(Dedicated)
AHCLKRx
ACLKRx
AFSRx
AMUTEINx
AMUTEx
AFSXx
ACLKXx
AHCLKXx
AXRx[0]
AXRx[1]
AXRx[y]
Pins Function
Receive Master Clock
Receive Bit Clock
Receive Left/Right Clock or Frame Sync
Transmit Master Clock
Transmit Bit Clock
Transmit Left/Right Clock or Frame Sync
Transmit/Receive Serial Data Pin
Transmit/Receive Serial Data Pin
Transmit/Receive Serial Data Pin
Error Detection The McASPs DO NOT have
dedicated AMUTEINx pins.
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The McASP serial port is specifically designed for multichannel audio applications. Its key features are:Flexible clock and frame sync generation logic and on-chip dividersUp to sixteen transmit or receive data pins and serializersLarge number of serial data format options, including: TDM Frames with 2 to 32 time slots per frame (periodic) or 1 slot per frame (burst). Time slots of 8,12,16, 20, 24, 28, and 32 bits. First bit delay 0, 1, or 2 clocks. MSB or LSB first bit order. Left- or right-aligned data words within time slotsDIT Mode (optional) with 384-bit Channel Status and 384-bit User Data registers.Extensive error-checking and mute generation logicAll unused pins GPIO-capable
Figure 4-25. McASP Block Diagram
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The three McASPs on C672x have different configurations (see Table 4-19 ). NOTE: McASP2 is notavailable on the C6722B and C6720.
Table 4-19. McASP Configurations on C672x DSP
McASP DIT CLOCK PINS DATA PINS COMMENTS
McASP0 No AHCLKX0/AHCLKX2, ACLKX0, AFSX0 Up to 16 AHCLKX0/AHCLKX2 share pin.AHCLKR0/AHCLKR1, ACLKR0, AFSR0 AHCLKR0/AHCLKR1 share pin.McASP1 No AHCLKX1, ACLKX1, AFSX1, ACLKR1, AFSR1 Up to 6 AHCLKR0/AHCLKR1 share pinMcASP2 Yes ACLKX2, AFSX2, AHCLKR2, ACLKR2, AFSR2 Up to 2 Full functionality on C6727B. On(Only available on the C6727B.) C6726B, functions only as DIT since onlyAHCLKX0/AHCLKX2 is available.Not available on the C6722B and C6720.
NOTE: The McASPs do not have dedicated AMUTEINx pins. Instead they can select one of the pinslisted in Table 4-21 ,Table 4-22 , and Table 4-23 to use as a mute input.
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4.13.1 McASP Peripheral Registers Description(s)
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Table 4-20 is a list of the McASP registers. For more information about these registers, see theTMS320C672x DSP Multichannel Audio Serial Port (McASP) Reference Guide (literature numberSPRU878).
Table 4-20. McASP Registers Accessed Through Peripheral Configuration Bus
McASP0 McASP1 McASP2
REGISTERBYTE BYTE BYTE DESCRIPTIONNAMEADDRESS ADDRESS ADDRESS
Device-Level Configuration Registers Controlling McASP
0x4000 0018 0x4000 001C 0x4000 0020 CFGMCASPx Selects the peripheral pin to be used as AMUTEINx
McASP Internal Registers
0x4400 0000 0x4500 0000 0x4600 0000 PID Peripheral identification register0x4400 0004 0x4500 0004 0x4600 0004 PWRDEMU Power down and emulation management register0x4400 0010 0x4500 0010 0x4600 0010 PFUNC Pin function register0x4400 0014 0x4500 0014 0x4600 0014 PDIR Pin direction register0x4400 0018 0x4500 0018 0x4600 0018 PDOUT Pin data output register0x4400 001C 0x4500 001C 0x4600 001C PDIN (reads) Read returns: Pin data input registerPDSET (writes) Writes affect: Pin data set register(alternate write address: PDOUT)0x4400 0020 0x4500 0020 0x4600 0020 PDCLR Pin data clear register (alternate write address: PDOUT)0x4400 0044 0x4500 0044 0x4600 0044 GBLCTL Global control register0x4400 0048 0x4500 0048 0x4600 0048 AMUTE Audio mute control register0x4400 004C 0x4500 004C 0x4600 004C DLBCTL Digital loopback control register0x4400 0050 0x4500 0050 0x4600 0050 DITCTL DIT mode control register0x4400 0060 0x4500 0060 0x4600 0060 RGBLCTL Receiver global control register: Alias of GBLCTL, onlyreceive bits are affected - allows receiver to be resetindependently from transmitter0x4400 0064 0x4500 0064 0x4600 0064 RMASK Receive format unit bit mask register0x4400 0068 0x4500 0068 0x4600 0068 RFMT Receive bit stream format register0x4400 006C 0x4500 006C 0x4600 006C AFSRCTL Receive frame sync control register0x4400 0070 0x4500 0070 0x4600 0070 ACLKRCTL Receive clock control register0x4400 0074 0x4500 0074 0x4600 0074 AHCLKRCTL Receive high-frequency clock control register0x4400 0078 0x4500 0078 0x4600 0078 RTDM Receive TDM time slot 0-31 register0x4400 007C 0x4500 007C 0x4600 007C RINTCTL Receiver interrupt control register0x4400 0080 0x4500 0080 0x4600 0080 RSTAT Receiver status register0x4400 0084 0x4500 0084 0x4600 0084 RSLOT Current receive TDM time slot register0x4400 0088 0x4500 0088 0x4600 0088 RCLKCHK Receive clock check control register0x4400 008C 0x4500 008C 0x4600 008C REVTCTL Receiver DMA event control register0x4400 00A0 0x4500 00A0 0x4600 00A0 XGBLCTL Transmitter global control register. Alias of GBLCTL, onlytransmit bits are affected - allows transmitter to be resetindependently from receiver0x4400 00A4 0x4500 00A4 0x4600 00A4 XMASK Transmit format unit bit mask register0x4400 00A8 0x4500 00A8 0x4600 00A8 XFMT Transmit bit stream format register0x4400 00AC 0x4500 00AC 0x4600 00AC AFSXCTL Transmit frame sync control register0x4400 00B0 0x4500 00B0 0x4600 00B0 ACLKXCTL Transmit clock control register0x4400 00B4 0x4500 00B4 0x4600 00B4 AHCLKXCTL Transmit high-frequency clock control register0x4400 00B8 0x4500 00B8 0x4600 00B8 XTDM Transmit TDM time slot 0-31 register0x4400 00BC 0x4500 00BC 0x4600 00BC XINTCTL Transmitter interrupt control register0x4400 00C0 0x4500 00C0 0x4600 00C0 XSTAT Transmitter status register0x4400 00C4 0x4500 00C4 0x4600 00C4 XSLOT Current transmit TDM time slot register
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Table 4-20. McASP Registers Accessed Through Peripheral Configuration Bus (continued)
McASP0 McASP1 McASP2
REGISTERBYTE BYTE BYTE DESCRIPTIONNAMEADDRESS ADDRESS ADDRESS
0x4400 00C8 0x4500 00C8 0x4600 00C8 XCLKCHK Transmit clock check control register0x4400 00CC 0x4500 00CC 0x4600 00CC XEVTCTL Transmitter DMA event control register 0x4600 0100 DITCSRA0 Left channel status register 0 0x4600 0104 DITCSRA1 Left channel status register 1 0x4600 0108 DITCSRA2 Left channel status register 2 0x4600 010C DITCSRA3 Left channel status register 3 0x4600 0110 DITCSRA4 Left channel status register 4 0x4600 0114 DITCSRA5 Left channel status register 5 0x4600 0118 DITCSRB0 Right channel status register 0 0x4600 011C DITCSRB1 Right channel status register 1 0x4600 0120 DITCSRB2 Right channel status register 2 0x4600 0124 DITCSRB3 Right channel status register 3 0x4600 0128 DITCSRB4 Right channel status register 4 0x4600 012C DITCSRB5 Right channel status register 5 0x4600 0130 DITUDRA0 Left channel user data register 0 0x4600 0134 DITUDRA1 Left channel user data register 1 0x4600 0138 DITUDRA2 Left channel user data register 2 0x4600 013C DITUDRA3 Left channel user data register 3 0x4600 0140 DITUDRA4 Left channel user data register 4 0x4600 0144 DITUDRA5 Left channel user data register 5 0x4600 0148 DITUDRB0 Right channel user data register 0 0x4600 014C DITUDRB1 Right channel user data register 1 0x4600 0150 DITUDRB2 Right channel user data register 2 0x4600 0154 DITUDRB3 Right channel user data register 3 0x4600 0158 DITUDRB4 Right channel user data register 4 0x4600 015C DITUDRB5 Right channel user data register 50x4400 0180 0x4500 0180 0x4600 0180 SRCTL0 Serializer control register 00x4400 0184 0x4500 0184 0x4600 0184 SRCTL1 Serializer control register 10x4400 0188 0x4500 0188 SRCTL2 Serializer control register 20x4400 018C 0x4500 018C SRCTL3 Serializer control register 30x4400 0190 0x4500 0190 SRCTL4 Serializer control register 40x4400 0194 0x4500 0194 SRCTL5 Serializer control register 50x4400 0198 SRCTL6 Serializer control register 60x4400 019C SRCTL7 Serializer control register 70x4400 01A0 SRCTL8 Serializer control register 80x4400 01A4 SRCTL9 Serializer control register 90x4400 01A8 SRCTL10 Serializer control register 100x4400 01AC SRCTL11 Serializer control register 110x4400 01B0 SRCTL12 Serializer control register 120x4400 01B4 SRCTL13 Serializer control register 130x4400 01B8 SRCTL14 Serializer control register 140x4400 01BC SRCTL15 Serializer control register 150x4400 0200 0x4500 0200 0x4600 0200 XBUF0
(1)
Transmit buffer register for serializer 00x4400 0204 0x4500 0204 0x4600 0204 XBUF1
(1)
Transmit buffer register for serializer 10x4400 0208 0x4500 0208 XBUF2
(1)
Transmit buffer register for serializer 2
(1) Writes to XRBUF originate from peripheral configuration bus only when XBUSEL = 1 in XFMT.
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Table 4-20. McASP Registers Accessed Through Peripheral Configuration Bus (continued)
McASP0 McASP1 McASP2
REGISTERBYTE BYTE BYTE DESCRIPTIONNAMEADDRESS ADDRESS ADDRESS
0x4400 020C 0x4500 020C XBUF3
(1)
Transmit buffer register for serializer 30x4400 0210 0x4500 0210 XBUF4
(1)
Transmit buffer register for serializer 40x4400 0214 0x4500 0214 XBUF5
(1)
Transmit buffer register for serializer 50x4400 0218 XBUF6
(1)
Transmit buffer register for serializer 60x4400 021C XBUF7
(1)
Transmit buffer register for serializer 70x4400 0220 XBUF8
(1)
Transmit buffer register for serializer 80x4400 0224 XBUF9
(1)
Transmit buffer register for serializer 90x4400 0228 XBUF10
(1)
Transmit buffer register for serializer 100x4400 022C XBUF11
(1)
Transmit buffer register for serializer 110x4400 0230 XBUF12
(1)
Transmit buffer register for serializer 120x4400 0234 XBUF13
(1)
Transmit buffer register for serializer 130x4400 0238 XBUF14
(1)
Transmit buffer register for serializer 140x4400 023C XBUF15
(1)
Transmit buffer register for serializer 150x4400 0280 0x4500 0280 0x4600 0280 RBUF0
(2)
Receive buffer register for serializer 00x4400 0284 0x4500 0284 0x4600 0284 RBUF1
(2)
Receive buffer register for serializer 10x4400 0288 0x4500 0288 RBUF2
(2)
Receive buffer register for serializer 20x4400 028C 0x4500 028C RBUF3
(2)
Receive buffer register for serializer 30x4400 0290 0x4500 0290 RBUF4
(2)
Receive buffer register for serializer 40x4400 0294 0x4500 0294 RBUF5
(2)
Receive buffer register for serializer 50x4400 0298 RBUF6
(2)
Receive buffer register for serializer 60x4400 029C RBUF7
(2)
Receive buffer register for serializer 70x4400 02A0 RBUF8
(2)
Receive buffer register for serializer 80x4400 02A4 RBUF9
(2)
Receive buffer register for serializer 90x4400 02A8 RBUF10
(2)
Receive buffer register for serializer 100x4400 02AC RBUF11
(2)
Receive buffer register for serializer 110x4400 02B0 RBUF12
(2)
Receive buffer register for serializer 120x4400 02B4 RBUF13
(2)
Receive buffer register for serializer 130x4400 02B8 RBUF14
(2)
Receive buffer register for serializer 140x4400 02BC RBUF15
(2)
Receive buffer register for serializer 15
(2) Reads from XRBUF originate on peripheral configuration bus only when RBUSEL = 1 in RFMT.
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Figure 4-26 shows the bit layout of the CFGMCASP0 register and Table 4-21 contains a description of thebits.
31 8Reserved
7 3 2 0
Reserved AMUTEIN0
R/W, 0
LEGEND: R/W = Read/Write; R = Read only; - n= value after reset
Figure 4-26. CFGMCASP0 Register Bit Layout (0x4000 0018)
Table 4-21. CFGMCASP0 Register Bit Field Description (0x4000 0018)
RESET READBIT NO. NAME DESCRIPTIONVALUE WRITE
31:3 Reserved N/A N/A Reads are indeterminate. Only 0s should be written to these bits.2:0 AMUTEIN0 0 R/W AMUTEIN0 Selects the source of the input to the McASP0 mute input.000 = Select the input to be a constant '0'001 = Select the input from AXR0[7]/SPI1_CLK010 = Select the input from AXR0[8]/AXR1[5]/SPI1_SOMI
011 = Select the input from AXR0[9]/AXR1[4]/SPI1_SIMO
100 = Select the input from AHCLKR2101 = Select the input from SPI0_SIMO110 = Select the input from SPI0_SCS/I2C1_SCL111 = Select the input from SPI0_ENA/I2C1_SDA
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Figure 4-27 shows the bit layout of the CFGMCASP1 register and Table 4-22 contains a description of thebits.
31 8Reserved
7 3 2 0
Reserved AMUTEIN1
R/W, 0
LEGEND: R/W = Read/Write; R = Read only; - n= value after reset
Figure 4-27. CFGMCASP1 Register Bit Layout (0x4000 001C)
Table 4-22. CFGMCASP1 Register Bit Field Description (0x4000 001C)
RESET READBIT NO. NAME DESCRIPTIONVALUE WRITE
31:3 Reserved N/A N/A Reads are indeterminate. Only 0s should be written to these bits.2:0 AMUTEIN1 0 R/W AMUTEIN1 Selects the source of the input to the McASP1 mute input.000 = Select the input to be a constant '0'001 = Select the input from AXR0[7]/SPI1_CLK010 = Select the input from AXR0[8]/AXR1[5]/SPI1_SOMI
011 = Select the input from AXR0[9]/AXR1[4]/SPI1_SIMO
100 = Select the input from AHCLKR2101 = Select the input from SPI0_SIMO110 = Select the input from SPI0_SCS/I2C1_SCL111 = Select the input from SPI0_ENA/I2C1_SDA
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Figure 4-28 shows the bit layout of the CFGMCASP2 register and Table 4-23 contains a description of thebits.
31 8Reserved
7 3 2 0
Reserved AMUTEIN2
R/W, 0
LEGEND: R/W = Read/Write; R = Read only; - n= value after reset
Figure 4-28. CFGMCASP2 Register Bit Layout (0x4000 0020)
Table 4-23. CFGMCASP2 Register Bit Field Description (0x4000 0020)
(1)
RESET READBIT NO. NAME DESCRIPTIONVALUE WRITE
31:3 Reserved N/A N/A Reads are indeterminate. Only 0s should be written to these bits.2:0 AMUTEIN2 0 R/W AMUTEIN2 Selects the source of the input to the McASP2 mute input.000 = Select the input to be a constant '0'001 = Select the input from AXR0[7]/SPI1_CLK010 = Select the input from AXR0[8]/AXR1[5]/SPI1_SOMI
011 = Select the input from AXR0[9]/AXR1[4]/SPI1_SIMO
100 = Select the input from AHCLKR2101 = Select the input from SPI0_SIMO110 = Select the input from SPI0_SCS/I2C1_SCL111 = Select the input from SPI0_ENA/I2C1_SDA
(1) CFGMCASP2 is reserved on the C6722B and C6720.
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4.13.2 McASP Electrical Data/Timing
4.13.2.1 Multichannel Audio Serial Port (McASP) Timing
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Table 4-24 and Table 4-25 assume testing over recommended operating conditions (see Figure 4-29 andFigure 4-30 ).
Table 4-24. McASP Timing Requirements
(1) (2)
NO. MIN MAX UNIT
Cycle time, AHCLKR external, AHCLKR input 201 t
c(AHCKRX)
nsCycle time, AHCLKX external, AHCLKX input 20Pulse duration, AHCLKR external, AHCLKR input 7.52 t
w(AHCKRX)
nsPulse duration, AHCLKX external, AHCLKX input 7.5Cycle time, ACLKR external, ACLKR input greater of 2P or 20 ns3 t
c(ACKRX)
nsCycle time, ACLKX external, ACLKX input greater of 2P or 20 nsPulse duration, ACLKR external, ACLKR input 104 t
w(ACKRX)
nsPulse duration, ACLKX external, ACLKX input 10Setup time, AFSR input to ACLKR internal 8Setup time, AFSX input to ACLKX internal 8Setup time, AFSR input to ACLKR external input 35 t
su(AFRXC-ACKRX)
nsSetup time, AFSX input to ACLKX external input 3Setup time, AFSR input to ACLKR external output 3Setup time, AFSX input to ACLKX external output 3Hold time, AFSR input after ACLKR internal 0Hold time, AFSX input after ACLKX internal 0Hold time, AFSR input after ACLKR external input 36 t
h(ACKRX-AFRX)
nsHold time, AFSX input after ACLKX external input 3Hold time, AFSR input after ACLKR external output 3Hold time, AFSX input after ACLKX external output 3Setup time, AXRn input to ACLKR internal 87 t
su(AXR-ACKRX)
Setup time, AXRn input to ACLKR external input 3 nsSetup time, AXRn input to ACLKR external output 3Hold time, AXRn input after ACLKR internal 38 t
h(ACKRX-AXR)
Hold time, AXRn input after ACLKR external input 3 nsHold time, AXRn input after ACLKR external output 3
(1) ACLKX internal ACLKXCTL.CLKXM = 1, PDIR.ACLKX = 1ACLKX external input ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 0ACLKX external output ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 1ACLKR internal ACLKRCTL.CLKRM = 1, PDIR.ACLKR =1ACLKR external input ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 0ACLKR external output ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 1(2) P = SYSCLK2 period
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Table 4-25. McASP Switching Characteristics
(1)
NO. PARAMETER MIN MAX UNIT
Cycle time, AHCLKR internal, AHCLKR output 20Cycle time, AHCLKR external, AHCLKR output 209 t
c(AHCKRX)
nsCycle time, AHCLKX internal, AHCLKX output 20Cycle time, AHCLKX external, AHCLKX output 20Pulse duration, AHCLKR internal, AHCLKR output (AHR/2) 2.5
(2)
Pulse duration, AHCLKR external, AHCLKR output (AHR/2) 2.5
(2)10 t
w(AHCKRX)
nsPulse duration, AHCLKX internal, AHCLKX output (AHX/2) 2.5
(3)
Pulse duration, AHCLKX external, AHCLKX output (AHX/2) 2.5
(3)
Cycle time, ACLKR internal, ACLKR output greater of 2P or 20 ns
(4)
Cycle time, ACLKR external, ACLKR output greater of 2P or 20 ns
(4)11 t
c(ACKRX)
nsCycle time, ACLKX internal, ACLKX output greater of 2P or 20 ns
(4)
Cycle time, ACLKX external, ACLKX output greater of 2P or 20 ns
(4)
Pulse duration, ACLKR internal, ACLKR output (AR/2) 2.5
(5)
Pulse duration, ACLKR external, ACLKR output (AR/2) 2.5
(5)12 t
w(ACKRX)
nsPulse duration, ACLKX internal, ACLKX output (AX/2) 2.5
(6)
Pulse duration, ACLKX external, ACLKX output (AX/2) 2.5
(6)
Delay time, ACLKR internal, AFSR output 5Delay time, ACLKX internal, AFSX output 5Delay time, ACLKR external input, AFSR output 10Delay time, ACLKX external input, AFSX output 10Delay time, ACLKR external output, AFSR output 10Delay time, ACLKX external output, AFSX output 1013 t
d(ACKRX-FRX)
nsDelay time, ACLKR internal, AFSR output –1Delay time, ACLKX internal, AFSX output –1Delay time, ACLKR external input, AFSR output 0Delay time, ACLKX external input, AFSX output 0Delay time, ACLKR external output, AFSR output 0Delay time, ACLKX external output, AFSX output 0Delay time, ACLKX internal, AXRn output –1 514 t
d(ACLKX-AXRV)
Delay time, ACLKX external input, AXRn output 0 10 nsDelay time, ACLKX external output, AXRn output 0 10Disable time, ACLKX internal, AXRn output –3 1015 t
dis(ACKX-AXRHZ)
Disable time, ACLKX external input, AXRn output –3 10 nsDisable time, ACLKX external output, AXRn output –3 10
(1) ACLKX internal ACLKXCTL.CLKXM = 1, PDIR.ACLKX = 1ACLKX external input ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 0ACLKX external output ACLKXCTL.CLKXM = 0, PDIR.ACLKX = 1ACLKR internal ACLKRCTL.CLKRM = 1, PDIR.ACLKR =1ACLKR external input ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 0ACLKR external output ACLKRCTL.CLKRM = 0, PDIR.ACLKR = 1(2) AHR - Cycle time, AHCLKR.(3) AHX - Cycle time, AHCLKX.(4) P = SYSCLK2 period(5) AR - ACLKR period.(6) AX - ACLKX period.
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8
7
4
4
3
2
21
A0 A1 B0 B1A30 A31 B30 B31 C0 C1 C2 C3 C31
AHCLKR/X (Falling Edge Polarity)
AHCLKR/X (Rising Edge Polarity)
AFSR/X (Bit Width, 0 Bit Delay)
AFSR/X (Bit Width, 1 Bit Delay)
AFSR/X (Bit Width, 2 Bit Delay)
AFSR/X (Slot Width, 0 Bit Delay)
AFSR/X (Slot Width, 1 Bit Delay)
AFSR/X (Slot Width, 2 Bit Delay)
AXR[n] (Data In/Receive)
6
5
ACLKR/X (CLKRP = CLKXP = 0)(A)
ACLKR/X (CLKRP = CLKXP = 1)(B)
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A. For CLKRP = CLKXP = 0, the McASP transmitter is configured for rising edge (to shift data out) and the McASPreceiver is configured for falling edge (to shift data in).B. For CLKRP = CLKXP = 1, the McASP transmitter is configured for falling edge (to shift data out) and the McASPreceiver is configured for rising edge (to shift data in).
Figure 4-29. McASP Input Timings
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15
14
13
13
13
13
13
13
13
12
12
11
10
10
9
A0 A1 B0 B1A30 A31 B30 B31 C0 C1 C2 C3 C31
AHCLKR/X (Falling Edge Polarity)
AHCLKR/X (Rising Edge Polarity)
AFSR/X (Bit Width, 0 Bit Delay)
AFSR/X (Bit Width, 1 Bit Delay)
AFSR/X (Bit Width, 2 Bit Delay)
AFSR/X (Slot Width, 0 Bit Delay)
AFSR/X (Slot Width, 1 Bit Delay)
AFSR/X (Slot Width, 2 Bit Delay)
AXR[n] (Data Out/Transmit)
ACLKR/X (CLKRP = CLKXP = 0)(B)
ACLKR/X (CLKRP = CLKXP = 1)(A)
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A. For CLKRP = CLKXP = 1, the McASP transmitter is configured for falling edge (to shift data out) and the McASPreceiver is configured for rising edge (to shift data in).B. For CLKRP = CLKXP = 0, the McASP transmitter is configured for rising edge (to shift data out) and the McASPreceiver is configured for falling edge (to shift data in).
Figure 4-30. McASP Output Timings
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4.14 Serial Peripheral Interface Ports (SPI0, SPI1)
4.14.1 SPI Device-Specific Information
Peripheral
Configuration Bus
Interrupt and
DMA Requests
16-Bit Shift Register
16-Bit Buffer
16-Bit Emulation Buffer
C672x SPI Module
GPIO
Control
(all pins)
State
Machine
Clock
Control
SPIx_SIMO
SPIx_SOMI
SPIx_ENA
SPIx_SCS
SPIx_CLK
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Figure 4-31 is a block diagram of the SPI module, which is a simple shift register and buffer plus controllogic. Data is written to the shift register before transmission occurs and is read from the buffer at the endof transmission. The SPI can operate either as a master, in which case, it initiates a transfer and drivesthe SPIx_CLK pin, or as a slave. Four clock phase and polarity options are supported as well as manydata formatting options.
Figure 4-31. Block Diagram of SPI Module
The SPI supports 3-, 4-, and 5-pin operation with three basic pins (SPIx_CLK, SPIx_SIMO, andSPIx_SOMI) and two optional pins ( SPIx_SCS, SPIx_ENA).
The optional SPIx_SCS (Slave Chip Select) pin is most useful to enable in slave mode when there areother slave devices on the same SPI port. The C672x will only shift data and drive the SPIx_SOMI pinwhen SPIx_SCS is held low.
In slave mode, SPIx_ENA is an optional output and can be driven in either a push-pull or open-drainmanner. The SPIx_ENA output provides the status of the internal transmit buffer (SPIDAT0/1 registers). Infour-pin mode with the enable option, SPIx_ENA is asserted only when the transmit buffer is full, indicatingthat the slave is ready to begin another transfer. In five-pin mode, the SPIx_ENA is additionally qualifiedby SPIx_SCS being asserted. This allows a single handshake line to be shared by multiple slaves on thesame SPI bus.
In master mode, the SPIx_ENA pin is an optional input and the master can be configured to delay the startof the next transfer until the slave asserts SPIx_ENA. The addition of this handshake signal simplifies SPIcommunications and, on average, increases SPI bus throughput since the master does not need to delayeach transfer long enough to allow for the worst-case latency of the slave device. Instead, each transfercan begin as soon as both the master and slave have actually serviced the previous SPI transfer.
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Optional − Slave Chip Select
Optional Enable (Ready)
SLAVE SPIMASTER SPI
SPIx_SIMOSPIx_SIMO
SPIx_SOMI SPIx_SOMI
SPIx_CLK SPIx_CLK
SPIx_ENA SPIx_ENA
SPIx_SCS SPIx_SCS
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Figure 4-32. Illustration of SPI Master-to-SPI Slave Connection
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4.14.2 SPI Peripheral Registers Description(s)
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Table 4-26 is a list of the SPI registers.
Table 4-26. SPIx Configuration Registers
SPI0 SPI1
REGISTER NAME DESCRIPTIONBYTE ADDRESS BYTE ADDRESS
0x4700 0000 0x4800 0000 SPIGCR0 Global Control Register 00x4700 0004 0x4800 0004 SPIGCR1 Global Control Register 10x4700 0008 0x4800 0008 SPIINT0 Interrupt Register0x4700 000C 0x4800 000C SPILVL Interrupt Level Register0x4700 0010 0x4800 0010 SPIFLG Flag Register0x4700 0014 0x4800 0014 SPIPC0 Pin Control Register 0 (Pin Function)0x4700 0018 0x4800 0018 SPIPC1 Pin Control Register 1 (Pin Direction)0x4700 001C 0x4800 001C SPIPC2 Pin Control Register 2 (Pin Data In)0x4700 0020 0x4800 0020 SPIPC3 Pin Control Register 3 (Pin Data Out)0x4700 0024 0x4800 0024 SPIPC4 Pin Control Register 4 (Pin Data Set)0x4700 0028 0x4800 0028 SPIPC5 Pin Control Register 5 (Pin Data Clear)0x4700 002C 0x4800 002C Reserved Reserved - Do not write to this register0x4700 0030 0x4800 0030 Reserved Reserved - Do not write to this register0x4700 0034 0x4800 0034 Reserved Reserved - Do not write to this register0x4700 0038 0x4800 0038 SPIDAT0 Shift Register 0 (without format select)0x4700 003C 0x4800 003C SPIDAT1 Shift Register 1 (with format select)0x4700 0040 0x4800 0040 SPIBUF Buffer Register0x4700 0044 0x4800 0044 SPIEMU Emulation Register0x4700 0048 0x4800 0048 SPIDELAY Delay Register0x4700 004C 0x4800 004C SPIDEF Default Chip Select Register0x4700 0050 0x4800 0050 SPIFMT0 Format Register 00x4700 0054 0x4800 0054 SPIFMT1 Format Register 10x4700 0058 0x4800 0058 SPIFMT2 Format Register 20x4700 005C 0x4800 005C SPIFMT3 Format Register 30x4700 0060 0x4800 0060 TGINTVECT0 Interrupt Vector for SPI INT00x4700 0064 0x4800 0064 TGINTVECT1 Interrupt Vector for SPI INT1
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4.14.3 SPI Electrical Data/Timing
4.14.3.1 Serial Peripheral Interface (SPI) Timing
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Table 4-27 through Table 4-34 assume testing over recommended operating conditions (see Figure 4-33through Figure 4-36 ).
Table 4-27. General Timing Requirements for SPIx Master Modes
(1)
NO. MIN MAX UNIT
greater of 8P or1 t
c(SPC)M
Cycle Time, SPIx_CLK, All Master Modes 256P ns100 ns2 t
w(SPCH)M
Pulse Width High, SPIx_CLK, All Master Modes greater of 4P or 45 ns ns3 t
w(SPCL)M
Pulse Width Low, SPIx_CLK, All Master Modes greater of 4P or 45 ns nsPolarity = 0, Phase = 0,
2Pto SPIx_CLK risingPolarity = 0, Phase = 1,
0.5t
c(SPC)M
+ 2PDelay, initial data bit valid
to SPIx_CLK rising4 t
d(SIMO_SPC)M
on SPIx_SIMO to initial nsPolarity = 1, Phase = 0,edge on SPIx_CLK
(2)
2Pto SPIx_CLK fallingPolarity = 1, Phase = 1,
0.5t
c(SPC)M
+ 2Pto SPIx_CLK fallingPolarity = 0, Phase = 0,
15from SPIx_CLK risingPolarity = 0, Phase = 1,
15Delay, subsequent bits
from SPIx_CLK falling5 t
d(SPC_SIMO)M
valid on SPIx_SIMO after nsPolarity = 1, Phase = 0,transmit edge of SPIx_CLK
15from SPIx_CLK fallingPolarity = 1, Phase = 1,
15from SPIx_CLK risingPolarity = 0, Phase = 0,
0.5t
c(SPC)M
10from SPIx_CLK fallingPolarity = 0, Phase = 1,Output hold time,
0.5t
c(SPC)M
10from SPIx_CLK risingSPIx_SIMO valid after6 t
oh(SPC_SIMO)M
nsreceive edge of SPIxCLK,
Polarity = 1, Phase = 0,
0.5t
c(SPC)M
10except for final bit
(3)
from SPIx_CLK risingPolarity = 1, Phase = 1,
0.5t
c(SPC)M
10from SPIx_CLK fallingPolarity = 0, Phase = 0,
0.5P + 15to SPIx_CLK fallingPolarity = 0, Phase = 1,
0.5P + 15Input Setup Time,
to SPIx_CLK rising7 t
su(SOMI_SPC)M
SPIx_SOMI valid before nsPolarity = 1, Phase = 0,receive edge of SPIx_CLK
0.5P + 15to SPIx_CLK risingPolarity = 1, Phase = 1,
0.5P + 15to SPIx_CLK fallingPolarity = 0, Phase = 0,
0.5P + 5from SPIx_CLK fallingPolarity = 0, Phase = 1,
0.5P + 5Input Hold Time,
from SPIx_CLK rising8 t
ih(SPC_SOMI)M
SPIx_SOMI valid after nsPolarity = 1, Phase = 0,receive edge of SPIx_CLK
0.5P + 5from SPIx_CLK risingPolarity = 1, Phase = 1,
0.5P + 5from SPIx_CLK falling
(1) P = SYSCLK2 period(2) First bit may be MSB or LSB depending upon SPI configuration. MO(0) refers to first bit and MO(n) refers to last bit output onSPIx_SIMO. MI(0) refers to the first bit input and MI(n) refers to the last bit input on SPIx_SOMI.(3) The final data bit will be held on the SPIx_SIMO pin until the SPIDAT0 or SPIDAT1 register is written with new data.
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Table 4-28. General Timing Requirements for SPIx Slave Modes
(1)
NO. MIN MAX UNIT
greater of 8P or9 t
c(SPC)S
Cycle Time, SPIx_CLK, All Slave Modes 256P ns100 nsgreater of 4P or10 t
w(SPCH)S
Pulse Width High, SPIx_CLK, All Slave Modes ns45 nsgreater of 4P or11 t
w(SPCL)S
Pulse Width Low, SPIx_CLK, All Slave Modes ns45 nsPolarity = 0, Phase = 0,
2Pto SPIx_CLK risingSetup time, transmit data
Polarity = 0, Phase = 1,
2Pwritten to SPI and output
to SPIx_CLK rising12 t
su(SOMI_SPC)S
onto SPIx_SOMI pin before nsPolarity = 1, Phase = 0,initial clock edge from
2Pto SPIx_CLK fallingmaster.
(2) (3)
Polarity = 1, Phase = 1,
2Pto SPIx_CLK fallingPolarity = 0, Phase = 0,
2P + 15from SPIx_CLK risingPolarity = 0, Phase = 1,
2P + 15Delay, subsequent bits
from SPIx_CLK falling13 t
d(SPC_SOMI)S
valid on SPIx_SOMI after nsPolarity = 1, Phase = 0,transmit edge of SPIx_CLK
2P + 15from SPIx_CLK fallingPolarity = 1, Phase = 1,
2P + 15from SPIx_CLK risingPolarity = 0, Phase = 0,
0.5t
c(SPC)S
10from SPIx_CLK fallingPolarity = 0, Phase = 1,Output hold time,
0.5t
c(SPC)S
10from SPIx_CLK risingSPIx_SOMI valid after14 t
oh(SPC_SOMI)S
nsreceive edge of SPIxCLK,
Polarity = 1, Phase = 0,
0.5t
c(SPC)S
10except for final bit
(4)
from SPIx_CLK risingPolarity = 1, Phase = 1,
0.5t
c(SPC)S
10from SPIx_CLK fallingPolarity = 0, Phase = 0,
0.5P + 15to SPIx_CLK fallingPolarity = 0, Phase = 1,
0.5P + 15Input Setup Time,
to SPIx_CLK rising15 t
su(SIMO_SPC)S
SPIx_SIMO valid before nsPolarity = 1, Phase = 0,receive edge of SPIx_CLK
0.5P + 15to SPIx_CLK risingPolarity = 1, Phase = 1,
0.5P + 15to SPIx_CLK fallingPolarity = 0, Phase = 0,
0.5P + 5from SPIx_CLK fallingPolarity = 0, Phase = 1,
0.5P + 5Input Hold Time,
from SPIx_CLK rising16 t
ih(SPC_SIMO)S
SPIx_SIMO valid after nsPolarity = 1, Phase = 0,receive edge of SPIx_CLK
0.5P + 5from SPIx_CLK risingPolarity = 1, Phase = 1,
0.5P + 5from SPIx_CLK falling
(1) P = SYSCLK2 period(2) First bit may be MSB or LSB depending upon SPI configuration. SO(0) refers to first bit and SO(n) refers to last bit output onSPIx_SOMI. SI(0) refers to the first bit input and SI(n) refers to the last bit input on SPIx_SIMO.(3) Measured from the termination of the write of new data to the SPI module, as evidenced by new output data appearing on theSPIx_SOMI pin. In analyzing throughput requirements, additional internal bus cycles must be accounted for to allow data to be written tothe SPI module by either the DSP CPU or the dMAX.(4) The final data bit will be held on the SPIx_SOMI pin until the SPIDAT0 or SPIDAT1 register is written with new data.
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Table 4-29. Additional
(1)
SPI Master Timings, 4-Pin Enable Option
(2) (3)
NO. MIN MAX UNIT
Polarity = 0, Phase = 0,
3P + 15to SPIx_CLK risingPolarity = 0, Phase = 1,
0.5t
c(SPC)M
+ 3P + 15Delay from slave assertion of
to SPIx_CLK rising17 t
d(ENA_SPC)M
SPIx_ENA active to first nsPolarity = 1, Phase = 0,SPIx_CLK from master.
(4)
3P + 15to SPIx_CLK fallingPolarity = 1, Phase = 1,
0.5t
c(SPC)M
+ 3P + 15to SPIx_CLK fallingPolarity = 0, Phase = 0,
0.5t
c(SPC)Mfrom SPIx_CLK fallingPolarity = 0, Phase = 1,Max delay for slave to deassert
0from SPIx_CLK fallingSPIx_ENA after final SPIx_CLK18 t
d(SPC_ENA)M
nsedge to ensure master does not
Polarity = 1, Phase = 0,
0.5t
c(SPC)Mbegin the next transfer.
(5)
from SPIx_CLK risingPolarity = 1, Phase = 1,
0from SPIx_CLK rising
(1) These parameters are in addition to the general timings for SPI master modes (Table 4-27 ).(2) P = SYSCLK2 period(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four master clocking modes.(4) In the case where the master SPI is ready with new data before SPIx_ENA assertion.(5) In the case where the master SPI is ready with new data before SPIx_ENA deassertion.
Table 4-30. Additional
(1)
SPI Master Timings, 4-Pin Chip Select Option
(2) (3)
NO. MIN MAX UNIT
Polarity = 0, Phase = 0,
2P 10to SPIx_CLK risingPolarity = 0, Phase = 1,
0.5t
c(SPC)M
+ 2P 10to SPIx_CLK risingDelay from SPIx_SCS active to19 t
d(SCS_SPC)M
nsfirst SPIx_CLK
(4) (5)
Polarity = 1, Phase = 0,
2P 10to SPIx_CLK fallingPolarity = 1, Phase = 1,
0.5t
c(SPC)M
+ 2P 10to SPIx_CLK fallingPolarity = 0, Phase = 0,
0.5t
c(SPC)Mfrom SPIx_CLK fallingPolarity = 0, Phase = 1,
0Delay from final SPIx_CLK edge
from SPIx_CLK falling20 t
d(SPC_SCS)M
to master deasserting SPIx_SCS nsPolarity = 1, Phase = 0,(6) (7)
0.5t
c(SPC)Mfrom SPIx_CLK risingPolarity = 1, Phase = 1,
0from SPIx_CLK rising
(1) These parameters are in addition to the general timings for SPI master modes (Table 4-27 ).(2) P = SYSCLK2 period(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four master clocking modes.(4) In the case where the master SPI is ready with new data before SPIx_SCS assertion.(5) This delay can be increased under software control by the register bit field SPIDELAY.C2TDELAY[4:0].(6) Except for modes when SPIDAT1.CSHOLD is enabled and there is additional data to transmit. In this case, SPIx_SCS will remainasserted.
(7) This delay can be increased under software control by the register bit field SPIDELAY.T2CDELAY[4:0].
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Table 4-31. Additional
(1)
SPI Master Timings, 5-Pin Option
(2) (3)
NO. MIN MAX UNIT
Polarity = 0, Phase = 0,
0.5t
c(SPC)Mfrom SPIx_CLK fallingMax delay for slave to
Polarity = 0, Phase = 1,deassert SPIx_ENA after
0from SPIx_CLK fallingfinal SPIx_CLK edge to18 t
d(SPC_ENA)M
nsensure master does not
Polarity = 1, Phase = 0,
0.5t
c(SPC)Mbegin the next
from SPIx_CLK risingtransfer.
(4)
Polarity = 1, Phase = 1,
0from SPIx_CLK risingPolarity = 0, Phase = 0,
0.5t
c(SPC)Mfrom SPIx_CLK fallingPolarity = 0, Phase = 1,Delay from final
0from SPIx_CLK fallingSPIx_CLK edge to20 t
d(SPC_SCS)M
nsmaster deasserting
Polarity = 1, Phase = 0,
0.5t
c(SPC)MSPIx_SCS
(5) (6)
from SPIx_CLK risingPolarity = 1, Phase = 1,
0from SPIx_CLK risingMax delay for slave SPI to drive SPIx_ENA valid21 t
d(SCSL_ENAL)M
after master asserts SPIx_SCS to delay the 0.5P nsmaster from beginning the next transfer.
Polarity = 0, Phase = 0,
2P 10to SPIx_CLK risingPolarity = 0, Phase = 1,
0.5t
c(SPC)M
+ 2P 10Delay from SPIx_SCS
to SPIx_CLK rising22 t
d(SCS_SPC)M
active to first nsPolarity = 1, Phase = 0,SPIx_CLK
(7) (8) (9)
2P 10to SPIx_CLK fallingPolarity = 1, Phase = 1,
0.5t
c(SPC)M
+ 2P 10to SPIx_CLK fallingPolarity = 0, Phase = 0,
3P + 15to SPIx_CLK risingPolarity = 0, Phase = 1,
0.5t
c(SPC)M
+ 3P + 15Delay from assertion of
to SPIx_CLK rising23 t
d(ENA_SPC)M
SPIx_ENA low to first nsPolarity = 1, Phase = 0,SPIx_CLK edge.
(10)
3P + 15to SPIx_CLK fallingPolarity = 1, Phase = 1,
0.5t
c(SPC)M
+ 3P + 15to SPIx_CLK falling
(1) These parameters are in addition to the general timings for SPI master modes (Table 4-27 ).(2) P = SYSCLK2 period(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four master clocking modes.(4) In the case where the master SPI is ready with new data before SPIx_ENA deassertion.(5) Except for modes when SPIDAT1.CSHOLD is enabled and there is additional data to transmit. In this case, SPIx_SCS will remainasserted.
(6) This delay can be increased under software control by the register bit field SPIDELAY.T2CDELAY[4:0].(7) If SPIx_ENA is asserted immediately such that the transmission is not delayed by SPIx_ENA.(8) In the case where the master SPI is ready with new data before SPIx_SCS assertion.(9) This delay can be increased under software control by the register bit field SPIDELAY.C2TDELAY[4:0].(10) If SPIx_ENA was initially deasserted high and SPIx_CLK is delayed.
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Table 4-32. Additional
(1)
SPI Slave Timings, 4-Pin Enable Option
(2) (3)
NO. MIN MAX UNIT
Polarity = 0, Phase = 0,
P 10 3P + 15from SPIx_CLK fallingPolarity = 0, Phase = 1,
–0.5t
c(SPC)M
+ P 10 –0.5t
c(SPC)M
+ 3P + 15Delay from final
from SPIx_CLK falling24 t
d(SPC_ENAH)S
SPIx_CLK edge to slave nsPolarity = 1, Phase = 0,deasserting SPIx_ENA.
P 10 3P + 15from SPIx_CLK risingPolarity = 1, Phase = 1,
–0.5t
c(SPC)M
+ P 10 –0.5t
c(SPC)M
+ 3P + 15from SPIx_CLK rising
(1) These parameters are in addition to the general timings for SPI slave modes (Table 4-28 ).(2) P = SYSCLK2 period(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four slave clocking modes.
Table 4-33. Additional
(1)
SPI Slave Timings, 4-Pin Chip Select Option
(2) (3)
NO. MIN MAX UNIT
Required delay from SPIx_SCS asserted at slave to first25 t
d(SCSL_SPC)S
P nsSPIx_CLK edge at slave.
Polarity = 0, Phase = 0,
0.5t
c(SPC)M
+ P + 10from SPIx_CLK fallingPolarity = 0, Phase = 1,
P + 10Required delay from final
from SPIx_CLK falling26 t
d(SPC_SCSH)S
SPIx_CLK edge before nsPolarity = 1, Phase = 0,SPIx_SCS is deasserted.
0.5t
c(SPC)M
+ P + 10from SPIx_CLK risingPolarity = 1, Phase = 1,
P + 10from SPIx_CLK risingDelay from master asserting SPIx_SCS to slave driving27 t
ena(SCSL_SOMI)S
P + 15 nsSPIx_SOMI validDelay from master deasserting SPIx_SCS to slave 3-stating28 t
dis(SCSH_SOMI)S
P + 15 nsSPIx_SOMI
(1) These parameters are in addition to the general timings for SPI slave modes (Table 4-28 ).(2) P = SYSCLK2 period(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four slave clocking modes.
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Table 4-34. Additional
(1)
SPI Slave Timings, 5-Pin Option
(2) (3)
NO. MIN MAX UNIT
Required delay from SPIx_SCS asserted at slave to first25 t
d(SCSL_SPC)S
P nsSPIx_CLK edge at slave.
Polarity = 0, Phase = 0,
0.5t
c(SPC)M
+ P + 10from SPIx_CLK fallingPolarity = 0, Phase = 1,
P + 10Required delay from final
from SPIx_CLK falling26 t
d(SPC_SCSH)S
SPIx_CLK edge before nsPolarity = 1, Phase = 0,SPIx_SCS is deasserted.
0.5t
c(SPC)M
+ P + 10from SPIx_CLK risingPolarity = 1, Phase = 1,
P + 10from SPIx_CLK risingDelay from master asserting SPIx_SCS to slave driving27 t
ena(SCSL_SOMI)S
P + 15 nsSPIx_SOMI validDelay from master deasserting SPIx_SCS to slave 3-stating28 t
dis(SCSH_SOMI)S
P + 15 nsSPIx_SOMI
Delay from master deasserting SPIx_SCS to slave driving29 t
ena(SCSL_ENA)S
15 nsSPIx_ENA valid
Polarity = 0, Phase = 0,
2P + 15from SPIx_CLK fallingPolarity = 0, Phase = 1,Delay from final clock receive
2P + 15from SPIx_CLK risingedge on SPIx_CLK to slave30 t
dis(SPC_ENA)S
ns3-stating or driving high
Polarity = 1, Phase = 0,
2P + 15SPIx_ENA.
(4)
from SPIx_CLK risingPolarity = 1, Phase = 1,
2P + 15from SPIx_CLK falling
(1) These parameters are in addition to the general timings for SPI slave modes (Table 4-28 ).(2) P = SYSCLK2 period(3) Figure shows only Polarity = 0, Phase = 0 as an example. Table gives parameters for all four slave clocking modes.(4) SPIx_ENA is driven low after the transmission completes if the SPIINT0.ENABLE_HIGHZ bit is programmed to 0. Otherwise it is3-stated. If 3-stated, an external pullup resistor should be used to provide a valid level to the master. This option is useful when tyingseveral SPI slave devices to a single master.
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SPIx_CLK
SPI_SIMO
SPI_SOMI
SPIx_CLK
SPI_SIMO
SPI_SOMI
SPIx_CLK
SPI_SIMO
SPI_SOMI
SPIx_CLK
SPI_SIMO
SPI_SOMI
MO(0) MO(1) MO(n−1) MO(n)
MI(0) MI(1) MI(n−1) MI(n)
MO(0) MO(1) MO(n−1) MO(n)
MI(0) MI(1) MI(n−1) MI(n)
MO(0) MO(1) MO(n−1) MO(n)
MI(0) MI(1) MI(n−1) MI(n)
MO(0) MO(1) MO(n−1) MO(n)
MI(0) MI(1) MI(n−1) MI(n)
6
6
7
7
7
7
8
8
8
8
32
6
1
4
4
4
45
5
56
MASTER MODE
POLARITY = 0 PHASE = 0
MASTER MODE
POLARITY = 0 PHASE = 1
MASTER MODE
POLARITY = 1 PHASE = 0
MASTER MODE
POLARITY = 1 PHASE = 1
5
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Figure 4-33. SPI Timings—Master Mode
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SPIx_CLK
SPI_SIMO
SPI_SOMI
SPIx_CLK
SPI_SIMO
SPI_SOMI
SPIx_CLK
SPI_SIMO
SPI_SOMI
SPIx_CLK
SPI_SIMO
SPI_SOMI
SI(0) SI(1) SI(n−1) SI(n)
SO(0) SO(1) SO(n−1) SO(n)
SI(0) SI(1) SI(n−1) SI(n)
SO(0) SO(1) SO(n−1) SO(n)
SI(0) SI(1) SI(n−1) SI(n)
SO(0) SO(1) SO(n−1) SO(n)
SI(0) SI(1) SI(n−1) SI(n)
SO(0) SO(1) SO(n−1) SO(n)
14
14
15
15
15
15
16
16
16
16
1110
14
9
12
12
12
12
13
13
13
13
14
SLAVE MODE
POLARITY = 0 PHASE = 0
SLAVE MODE
POLARITY = 0 PHASE = 1
SLAVE MODE
POLARITY = 1 PHASE = 0
SLAVE MODE
POLARITY = 1 PHASE = 1
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Figure 4-34. SPI Timings—Slave Mode
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MASTER MODE 4 PIN WITH CHIP SELECT
SPIx_CLK
SPI_SIMO
SPI_SOMI
SPIx_ENA
SPIx_CLK
SPI_SIMO
SPI_SOMI
SPIx_SCS
SPIx_CLK
SPI_SIMO
SPI_SOMI
SPIx_ENA
SPIx_SCS
MO(0) MO(1) MO(n−1) MO(n)
MI(0) MI(1) MI(n−1) MI(n)
MO(0) MO(1) MO(n−1) MO(n)
MI(0) MI(1) MI(n−1) MI(n)
MO(0)
MO(1)
MO(n−1) MO(n)
MI(0) MI(1) MI(n−1) MI(n)
17
19
21
22
23
20
18
20
18
MASTER MODE 4 PIN WITH ENABLE
MASTER MODE 5 PIN
A. DESELECTED IS PROGRAMMABLE EITHER HIGH OR
3−STATE (REQUIRES EXTERNAL PULLUP)
DESEL(A) DESEL(A)
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Figure 4-35. SPI Timings—Master Mode (4-Pin and 5-Pin)
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27
SPIx_CLK
SPI_SOMI
SPI_SIMO
SPIx_ENA
SPIx_CLK
SPI_SOMI
SPI_SIMO
SPIx_SCS
SPIx_CLK
SPI_SOMI
SPI_SIMO
SPIx_ENA
SPIx_SCS
SO(0) SO(1) SO(n−1) SO(n)
SI(0) SI(1) SI(n−1) SI(n)
SO(0) SO(1)
SO(n−1)
SO(n)
SI(0) SI(1) SI(n−1) SI(n)
SO(0)
SO(1)
SO(n−1) SO(n)
SI(0) SI(1) SI(n−1) SI(n)
24
26
28
26
30
28
25
25
27
29
SLAVE MODE 4 PIN WITH ENABLE
SLAVE MODE 4 PIN WITH CHIP SELECT
SLAVE MODE 5 PIN
DESEL(A) DESEL(A)
A. DESELECTED IS PROGRAMMABLE EITHER HIGH OR
3−STATE (REQUIRES EXTERNAL PULLUP)
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Figure 4-36. SPI Timings—Slave Mode (4-Pin and 5-Pin)
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4.15 Inter-Integrated Circuit Serial Ports (I2C0, I2C1)
4.15.1 I2C Device-Specific Information
Peripheral
Configuration
Bus
Noise
Filter
Noise
Filter
Clock Prescaler
I2CPSCx Prescaler
Register
Bit Clock Generator
I2CCLKHx Clock Divide
High Register
I2CCLKLx Clock Divide
Low Register
Control
I2CCOARx Own Address
Register
I2CSARx Slave Address
Register
I2CCMDRx Mode Register
I2CEMDRx Extended Mode
Register
I2CCNTx Data Count
Register
I2CPID1 Peripheral ID
Register 1
I2CPID2 Peripheral ID
Register 2
Transmit
I2CXSRx Transmit Shift
Register
I2CDXRx Transmit Buffer
Receive
I2CDRRx Receive Buffer
I2CRSRx Receive Shift
Register
I2Cx_SCL
I2Cx_SDA
C672x I2C Module
Control
Interrupt/DMA
I2CIERx Interrupt Enable
Register
I2CSTRx Interrupt Status
Register
I2CSRCx Interrupt Source
Register
Control
I2CPFUNC Pin Function
Register
I2CPDIR Pin Direction
Register
I2CPDIN Pin Data In
Register
I2CPDOUT Pin Data Out
Register
I2CPDSET Pin Data Set
Register
I2CPDCLR Pin Data Clear
Register
Interrupt DMA
Requests
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Having two I2C modules on the C672x simplifies system architecture, since one module may be used bythe DSP to control local peripherals ICs (DACs, ADCs, etc.) while the other may be used to communicatewith other controllers in a system or to implement a user interface. Figure 4-37 is block diagram of theC672x I2C Module.
Each I2C port supports:Compatible with Philips
®
I2C Specification Revision 2.1 (January 2000)Fast Mode up to 400 Kbps (no fail-safe I/O buffers)Noise Filter to Remove Noise 50 ns or lessSeven- and Ten-Bit Device Addressing ModesMaster (Transmit/Receive) and Slave (Transmit/Receive) FunctionalityEvents: DMA, Interrupt, or PollingGeneral-Purpose I/O Capability if not used as I2C
CAUTIONThe C672x I2C pins use a standard ±8 mA LVCMOS buffer, not the slow I/O bufferdefined in the I2C specification. Series resistors may be necessary to reduce noise atthe system level.
Figure 4-37. I2C Module Block Diagram
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4.15.2 I2C Peripheral Registers Description(s)
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Table 4-35 is a list of the I2C registers.
Table 4-35. I2Cx Configuration Registers
I2C0 I2C1
REGISTER NAME DESCRIPTIONBYTE ADDRESS BYTE ADDRESS
0x4900 0000 0x4A00 0000 I2COAR Own Address Register0x4900 0004 0x4A00 0004 I2CIER Interrupt Enable Register0x4900 0008 0x4A00 0008 I2CSTR Interrupt Status Register0x4900 000C 0x4A00 000C I2CCLKL Clock Low Time Divider Register0x4900 0010 0x4A00 0010 I2CCLKH Clock High Time Divider Register0x4900 0014 0x4A00 0014 I2CCNT Data Count Register0x4900 0018 0x4A00 0018 I2CDRR Data Receive Register0x4900 001C 0x4A00 001C I2CSAR Slave Address Register0x4900 0020 0x4A00 0020 I2CDXR Data Transmit Register0x4900 0024 0x4A00 0024 I2CMDR Mode Register0x4900 0028 0x4A00 0028 I2CISR Interrupt Source Register0x4900 002C 0x4A00 002C I2CEMDR Extended Mode Register0x4900 0030 0x4A00 0030 I2CPSC Prescale Register0x4900 0034 0x4A00 0034 I2CPID1 Peripheral Identification Register 10x4900 0038 0x4A00 0038 I2CPID2 Peripheral Identification Register 20x4900 0048 0x4A00 0048 I2CPFUNC Pin Function Register0x4900 004C 0x4A00 004C I2CPDIR Pin Direction Register0x4900 0050 0x4A00 0050 I2CPDIN Pin Data Input Register0x4900 0054 0x4A00 0054 I2CPDOUT Pin Data Output Register0x4900 0058 0x4A00 0058 I2CPDSET Pin Data Set Register0x4900 005C 0x4A00 005C I2CPDCLR Pin Data Clear Register
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4.15.3 I2C Electrical Data/Timing
4.15.3.1 Inter-Integrated Circuit (I2C) Timing
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Table 4-36 and Table 4-37 assume testing over recommended operating conditions (see Figure 4-38 andFigure 4-39 ).
Table 4-36. I2C Input Timing Requirements
NO. MIN MAX UNIT
Standard Mode 101 t
c(SCL)
Cycle time, I2Cx_SCL µsFast Mode 2.5Standard Mode 4.7Setup time, I2Cx_SCL high before I2Cx_SDA2 t
su(SCLH-SDAL)
µslow
Fast Mode 0.6Standard Mode 43 t
h(SCLL-SDAL)
Hold time, I2Cx_SCL low after I2Cx_SDA low µsFast Mode 0.6Standard Mode 4.74 t
w(SCLL)
Pulse duration, I2Cx_SCL low µsFast Mode 1.3Standard Mode 45 t
w(SCLH)
Pulse duration, I2Cx_SCL high µsFast Mode 0.6Standard Mode 2506 t
su(SDA-SCLH)
Setup time, I2Cx_SDA before I2Cx_SCL high nsFast Mode 100Standard Mode 07 t
h(SDA-SCLL)
Hold time, I2Cx_SDA after I2Cx_SCL low µsFast Mode 0 0.9Standard Mode 4.78 t
w(SDAH)
Pulse duration, I2Cx_SDA high µsFast Mode 1.3Standard Mode 10009 t
r(SDA)
Rise time, I2Cx_SDA nsFast Mode 20 + 0.1C
b
300Standard Mode 100010 t
r(SCL)
Rise time, I2Cx_SCL nsFast Mode 20 + 0.1C
b
300Standard Mode 30011 t
f(SDA)
Fall time, I2Cx_SDA nsFast Mode 20 + 0.1C
b
300Standard Mode 30012 t
f(SCL)
Fall time, I2Cx_SCL nsFast Mode 20 + 0.1C
b
300Standard Mode 4Setup time, I2Cx_SCL high before I2Cx_SDA13 t
su(SCLH-SDAH)
µshigh
Fast Mode 0.6Standard Mode N/A14 t
w(SP)
Pulse duration, spike (must be suppressed) nsFast Mode 0 50Standard Mode 40015 C
b
Capacitive load for each bus line pFFast Mode 400
Table 4-37. I2C Switching Characteristics
(1)
NO. PARAMETER MIN MAX UNIT
Standard Mode 1016 t
c(SCL)
Cycle time, I2Cx_SCL µsFast Mode 2.5Standard Mode 4.7Setup time, I2Cx_SCL high before I2Cx_SDA17 t
su(SCLH-SDAL)
µslow
Fast Mode 0.6Standard Mode 418 t
h(SDAL-SCLL)
Hold time, I2Cx_SCL low after I2Cx_SDA low µsFast Mode 0.6
(1) I2C must be configured correctly to meet the timings in Table 4-37 .
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10
84
3712
5
614
2
3
13
Stop Start Repeated
Start Stop
I2Cx_SDA
I2Cx_SCL
1
11 9
25
23 19
18 22 27
20
21
17
18
28
Stop Start Repeated
Start Stop
I2Cx_SDA
I2Cx_SCL
16
26 24
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Table 4-37. I2C Switching Characteristics (continued)
NO. PARAMETER MIN MAX UNIT
Standard Mode 4.719 t
w(SCLL)
Pulse duration, I2Cx_SCL low µsFast Mode 1.3Standard Mode 420 t
w(SCLH)
Pulse duration, I2Cx_SCL high µsFast Mode 0.6Standard Mode 250Setup time, I2Cx_SDA valid before I2Cx_SCL21 t
su(SDAV-SCLH)
nshigh
Fast Mode 100Standard Mode 022 t
h(SCLL-SDAV)
Hold time, I2Cx_SDA valid after I2Cx_SCL low µsFast Mode 0 0.9Standard Mode 4.723 t
w(SDAH)
Pulse duration, I2Cx_SDA high µsFast Mode 1.3Standard Mode 4Setup time, I2Cx_SCL high before I2Cx_SDA28 t
su(SCLH-SDAH)
µshigh
Fast Mode 0.6Standard Mode 10Capacitive load on each bus line from this29 C
b
pFdevice
Fast Mode 10
Figure 4-38. I2C Receive Timings
Figure 4-39. I2C Transmit Timings
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4.16 Real-Time Interrupt (RTI) Timer With Digital Watchdog
4.16.1 RTI/Digital Watchdog Device-Specific Information
McASP0,1,2
Transmit/Receive
DMA Events
McASP0,1,2
Transmit/Receive
DMA Events
Counter 0
32-Bit + 32-Bit Prescale
(Used by DSP BIOS)
Capture 0
32-Bit + 32-Bit Prescale
Counter 1
32-Bit + 32-Bit Prescale
Capture 1
32-Bit + 32-Bit Prescale
Compare 0
32-Bit RTI Interrupt 0
SYSCLK2
RTI Interrupt 1
Compare 1
32-Bit
RTI Interrupt 2
Compare 2
32-Bit
RTI Interrupt 3
Compare 3
32-Bit
RESET
(Internal Only)
Digital Watchdog
25-Bit Counter
Watchdog Key Register
16-Bit Key
Controlled by
CFGRTI Register
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C672x includes an RTI timer module which is used to generate periodic interrupts. This module alsoincludes an optional digital watchdog feature. Figure 4-40 contains a block diagram of the RTI module.
Figure 4-40. RTI Timer Block Diagram
The RTI timer module consists of two independent counters which are both clocked from SYSCLK2 (butmay be started individually and may have different prescaler settings).
The counters provide the timebase against which four output comparators operate. These comparatorsmay be programmed to generate periodic interrupts. The comparators include an adder whichautomatically updates the compare value after each periodic interrupt. This means that the DSP onlyneeds to initialize the comparator once with the interrupt period.
The two input captures can be triggered from any of the McASP0, McASP1, or McASP2 DMA events. Thedevice configuration register which selects the McASP events to measure is defined in Table 4-39 .
Measuring the time difference between these events provides an accurate measure of the sample rates atwhich the McASPs are transmitting and receiving. This measurement can be useful as a hardware assistfor a software asynchronous sample rate converter algorithm.
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4.16.2 RTI/Digital Watchdog Registers Description(s)
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The digital watchdog is disabled by default. Once enabled, a sequence of two 16-bit key values (0xE51Afollowed by 0xA35C in two separate writes) must be continually written to the key register before thewatchdog counter counts down to zero; otherwise, the DSP will be reset. This feature can be used toprovide an added measure of robustness against a software failure. If the application fails and ceases towrite to the watchdog key; the watchdog will respond by resetting the DSP and thereby restarting theapplication.
Note that Counter 0 and Compare 0 are used by DSP BIOS to generate the tick counter it requires;however, Capture 0 is still available for use by the application as well as the remaining RTI resources.
Table 4-38 is a list of the RTI registers.
Table 4-38. RTI Registers
BYTE ADDRESS REGISTER NAME DESCRIPTION
Device-Level Configuration Registers Controlling RTI
0x4000 0014 CFGRTI Selects the sources for the RTI input captures from among the six McASP DMA event.
RTI Internal Registers
0x4200 0000 RTIGCTRL Global Control Register. Starts / stops the counters.0x4200 0004 Reserved Reserved bit.0x4200 0008 RTICAPCTRL Capture Control. Controls the capture source for the counters.0x4200 000C RTICOMPCTRL Compare Control. Controls the source for the compare registers.0x4200 0010 RTIFRC0 Free-Running Counter 0. Current value of free-running counter 0.0x4200 0014 RTIUC0 Up-Counter 0. Current value of prescale counter 0.0x4200 0018 RTICPUC0 Compare Up-Counter 0. Compare value compared with prescale counter 0.0x4200 0020 RTICAFRC0 Capture Free-Running Counter 0. Current value of free-running counter 0 on externalevent.0x4200 0024 RTICAUC0 Capture Up-Counter 0. Current value of prescale counter 0 on external event.0x4200 0030 RTIFRC1 Free-Running Counter 1. Current value of free-running counter 1.0x4200 0034 RTIUC1 Up-Counter 1. Current value of prescale counter 1.0x4200 0038 RTICPUC1 Compare Up-Counter 1. Compare value compared with prescale counter 1.0x4200 0040 RTICAFRC1 Capture Free-Running Counter 1. Current value of free-running counter 1 on externalevent.0x4200 0044 RTICAUC1 Capture Up-Counter 1. Current value of prescale counter 1 on external event.0x4200 0050 RTICOMP0 Compare 0. Compare value to be compared with the counters.0x4200 0054 RTIUDCP0 Update Compare 0. Value to be added to the compare register 0 value on comparematch.0x4200 0058 RTICOMP1 Compare 1. Compare value to be compared with the counters.0x4200 005C RTIUDCP1 Update Compare 1. Value to be added to the compare register 1 value on comparematch.0x4200 0060 RTICOMP2 Compare 2. Compare value to be compared with the counters.0x4200 0064 RTIUDCP2 Update Compare 2. Value to be added to the compare register 2 value on comparematch.0x4200 0068 RTICOMP3 Compare 3. Compare value to be compared with the counters.0x4200 006C RTIUDCP3 Update Compare 3. Value to be added to the compare register 3 value on comparematch.0x4200 0070 Reserved Reserved bit.0x4200 0074 Reserved Reserved bit.0x4200 0080 RTISETINT Set Interrupt Enable. Sets interrupt enable bits int RTIINTCTRL without having to do aread-modify-write operation.0x4200 0084 RTICLEARINT Clear Interrupt Enable. Clears interrupt enable bits int RTIINTCTRL without having todo a read-modify-write operation.0x4200 0088 RTIINTFLAG Interrupt Flags. Interrupt pending bits.
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Table 4-38. RTI Registers (continued)
BYTE ADDRESS REGISTER NAME DESCRIPTION
0x4200 0090 RTIDWDCTRL Digital Watchdog Control. Enables the Digital Watchdog.0x4200 0094 RTIDWDPRLD Digital Watchdog Preload. Sets the experation time of the Digital Watchdog.0x4200 0098 RTIWDSTATUS Watchdog Status. Reflects the status of Analog and Digital Watchdog.0x4200 009C RTIWDKEY Watchdog Key. Correct written key values discharge the external capacitor.0x4200 00A0 RTIDWDCNTR Digital Watchdog Down-Counter
Figure 4-41 shows the bit layout of the CFGRTI register and Table 4-39 contains a description of the bits.31 8Reserved
7 6 4 3 2 0
Reserved CAPSEL1 Reserved CAPSEL0R/W, 0 R/W, 0
LEGEND: R/W = Read/Write; R = Read only; - n= value after reset
Figure 4-41. CFGRTI Register Bit Layout (0x4000 0014)
Table 4-39. CFGRTI Register Bit Field Description (0x4000 0014)
RESET READBIT NO. NAME DESCRIPTIONVALUE WRITE
31:7,3 Reserved N/A N/A Reads are indeterminate. Only 0s should be written to these bits.6:4 CAPSEL1 0 R/W CAPSEL0 selects the input to the RTI Input Capture 0 function.CAPSEL1 selects the input to the RTI Input Capture 1 function.2:0 CAPSEL0 0 R/W
The encoding is the same for both fields:000 = Select McASP0 Transmit DMA Event001 = Select McASP0 Receive DMA Event010 = Select McASP1 Transmit DMA Event011 = Select McASP1 Receive DMA Event100 = Select McASP2 Transmit DMA Event101 = Select McASP2 Receive DMA EventOther values are reserved and their effect is not determined.
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4.17 External Clock Input From Oscillator or CLKIN Pin
OSCVDD
C5
C7
C8
X1
RS
RB
OSCIN
OSCOUT
C6OSCVSS
CLKIN
Clock
Input
From
OSCIN
to
PLL
On-Chip Oscillator
(a)
External 3.3-V LVCMOS-Compatible Clock Source
(b)
OSCVDD
OSCIN
OSCOUT
OSCVSS
CLKIN
Clock
Input
From
CLKIN
to
PLL
CVDD
NC
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The C672x device includes two choices to provide an external clock input, which is fed to the on-chip PLLto generate high-frequency system clocks. These options are illustrated in Figure 4-42 .Figure 4-42 (a) illustrates the option that uses an on-chip oscillator with external crystal circuit.Figure 4-42 (b) illustrates the option that uses an external 3.3-V LVCMOS-compatible clock input withthe CLKIN pin.
Note that the two clock inputs are logically combined internally before the PLL so the clock input that is notused must be tied to ground.
Figure 4-42. C672x Clock Input Options
If the on-chip oscillator is chosen, then the recommended component values for Figure 4-42 (a) are listedin Table 4-40 .
Table 4-40. Recommended On-Chip Oscillator Components
FREQUENCY XTAL TYPE X
1
C
5
(1)
C
6
(1)
C
7
C
8
R
B
R
S
22.579 AT-49 KDS 1AF225796A 470 pF 470 pF 8 pF 8 pF 1 M 022.579 SMD-49 KDS 1AS225796AG 470 pF 470 pF 8 pF 8 pF 1 M 024.576 AT-49 KDS 1AF245766AAA 470 pF 470 pF 8 pF 8 pF 1 M 024.576 SMD-49 KDS 1AS245766AHA 470 pF 470 pF 8 pF 8 pF 1 M 0
(1) Capacitors C
5
and C
6
are used to reduce oscillator jitter, but are optional. If C
5
and C
6
are not used, then the node connectingcapacitors C
7
and C
8
should be tied to OSCV
SS
and OSCV
DD
should be tied to CV
DD
.
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4.17.1 Clock Electrical Data/Timing
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Table 4-41 assumes testing over recommended operating conditions.
Table 4-41. CLKIN Timing Requirements
NO. MIN MAX UNIT
1 f
osc
Oscillator frequency range (OSCIN/OSCOUT) 12 25 MHz2 t
c(CLKIN)
Cycle time, external clock driven on CLKIN 20 ns3 t
w(CLKINH)
Pulse width, CLKIN high 0.4t
c(CLKIN)
ns4 t
w(CLKINL)
Pulse width, CLKIN low 0.4t
c(CLKIN)
ns5 t
t(CLKIN)
Transition time, CLKIN 5 ns6 f
PLL
Frequency range of PLL input 12 50 MHz
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4.18 Phase-Locked Loop (PLL)
4.18.1 PLL Device-Specific Information
1
0
PLLEN
(PLL_CSR[0])
Divider
D0
(/1 to /32)
PLLREF PLL
x4 to x25
PLLOUT Divider
D1
(/1 to /32)
SYSCLK1 CPU and Memory
Divider
D2
(/1 to /32)
SYSCLK2 Peripherals and dMAX
Divider
D3
(/1 to /32)
SYSCLK3 EMIF
AUXCLK McASP0,1,2
Clock
Input
from
CLKIN or
OSCIN
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The C672x DSP generates the high-frequency internal clocks it requires through an on-chip PLL.
The input to the PLL is either from the on-chip oscillator (OSCIN pin) or from an external clock on theCLKIN pin. The PLL outputs four clocks that have programmable divider options. Figure 4-43 illustratesthe PLL Topology.
The PLL is disabled by default after a device reset. It must be configured by software according to theallowable operating conditions listed in Table 4-42 before enabling the DSP to run from the PLL by settingPLLEN = 1.
Figure 4-43. PLL Topology
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BOARD
DVDD (3.3 V)
EMI
Filter
10 mF0.1 mF
PLLHV
Place Filter and Capacitors as Close
to DSP as Possible
EMI Filter: TDK ACF451832−333, −223, −153, or −103,
Panasonic EXCCET103U, or Equivalent
+
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Table 4-42. Allowed PLL Operating Conditions
ALLOWED SETTING OR RANGEPARAMETER DEFAULT VALUE
MIN MAX
1 PLLRST = 1 assertion time during initialization N/A 125 ns2 Lock time before setting PLLEN = 1. After changing D0, PLLM, or N/A 187.5 µsinput clock.3 PLL input frequency (PLLREF after D0
(1)
) 12 MHz 50 MHz4 PLL multiplier values (PLLM) x13 x4 x255 PLL output frequency (PLLOUT before dividers D1, D2, D3)
(2)
N/A 140 MHz 600 MHz6 SYSCLK1 frequency (set by PLLM and dividers D0, D1) PLLOUT/1 Device Frequency
Specification7 SYSCLK2 frequency (set by PLLM and dividers D0, D2) PLLOUT/2 /2, /3, or /4 of SYSCLK18 SYSCLK3 frequency (set by PLLM and dividers D0, D3) PLLOUT/3 EMIF Frequency
Specification
(1) Some values for the D0 divider produce results outside of this range and should not be selected.(2) In general, selecting the PLL output clock rate closest to the maximum frequency will decrease clock jitter.
CAUTIONSYSCLK1, SYSCLK2, SYSCLK3 must be configured as aligned by setting ALNCTL[2:0]to '1'; and the PLLCMD.GOSET bit must be written every time the dividers D1, D2, andD3 are changed in order to make sure the change takes effect and preservesalignment.
CAUTIONWhen changing the PLL parameters which affect the SYSCLK1, SYSCLK2, SYSCLK3dividers, the bridge BR2 in Figure 2-4 must be reset by the CFGBRIDGE register. SeeTable 2-7 .
The PLL is an analog circuit and is sensitive to power supply noise. Therefore it has a dedicated 3.3-Vpower pin (PLLHV) that should be connected to DV
DD
at the board level through an external filter, asillustrated in Figure 4-44 .
Figure 4-44. PLL Power Supply Filter
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4.18.2 PLL Registers Description(s)
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Table 4-43 is a list of the PLL registers. For more information about these registers, see theTMS320C672x DSP Software-Programmable Phase-Locked Loop (PLL) Controller Reference Guide(literature number SPRU879).
Table 4-43. PLL Controller Registers
BYTE ADDRESS REGISTER NAME DESCRIPTION
0x4100 0000 PLLPID PLL controller peripheral identification register0x4100 0100 PLLCSR PLL control/status register0x4100 0110 PLLM PLL multiplier control register0x4100 0114 PLLDIV0 PLL controller divider register 00x4100 0118 PLLDIV1 PLL controller divider register 10x4100 011C PLLDIV2 PLL controller divider register 20x4100 0120 PLLDIV3 PLL controller divider register 30x4100 0138 PLLCMD PLL controller command register0x4100 013C PLLSTAT PLL controller status register0x4100 0140 ALNCTL PLL controller clock align control register0x4100 0148 CKEN Clock enable control register0x4100 014C CKSTAT Clock status register0x4100 0150 SYSTAT SYSCLK status register
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5 Application Example
256K
Bytes
RAM
Bytes
ROM
384K
Memory Controller
C67x+
DSP Core
Program
Cache
Crossbar Switch
EMIF UHPIdMAX
McASP0
SPI1
McASP1
I2C0
I2C1
RTI
SPIO
McASP2
PLL OSC
ASYNC
FLASH
133 MHz
SDRAM
DSP
Host
Microprocessor
Audio Zone 1
SPI or I2C
Control (optional)
Audio Zone 2
Audio Zone 3
CODEC, DIR,
ADC, DAC, DSD,
Network
Network
ADC, DAC, DSD,
CODEC, DIR,
TDM Port
Digital Out,
High Speed
Parallel Data DSP Control
SPI or I2C
6 Independent Audio
Zones (3 TX + 3 RX)
16 Serial Data Pins
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Figure 5-1 illustrates a high-level block diagram of the device and other devices to which it may typicallyconnect. See Section 1.2 for an overview of each major block.
A. UHPI is only available on the C6727B. McASP2 is not available on the C6722B and C6720.
Figure 5-1. TMS320C672x Audio DSP System Diagram
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6 Revision History
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This revision history highlights the technical changes made to the SPRS370D device-specific data sheetto make it an SPRS370E revision.
Scope: See table below.
ADDS/CHANGES/DELETES
Table 4-17 , UHPI Read and Write Timing Requirements:Parameter 38: Changed symbol from "t
h(HRDYH-DSL)
" to "t
h(HRDYL-DSH)
" Changed description from "Hold time, DS low after UHPI_HRDY rising edge" to "Hold time, DS high after UHPI_HRDY fallingedge"Table 4-27 , General Timing Requirements for SPIx Master Modes:Parameter 4 [t
d(SIMO_SPC)M
]: Updated MIN valuesTable 4-32 , Additional SPI Slave Timings, 4-Pin Enable Option:Parameter 24 [t
d(SPC_ENAH)S
]: Polarity = 0, Phase = 1: Updated MIN and MAX values Polarity = 1, Phase = 1: Updated MIN and MAX valuesTable 4-34 , Additional SPI Slave Timings, 5-Pin Option:Parameter 27 [t
ena(SCSL_SOMI)S
]: Updated MAX valueParameter 28 [t
dis(SCSH_SOMI)S
]: Updated MAX valueRemoved "PowerPAD™ PCB Footprint" section (Section 7.2.2 in SPRS370D)
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7 Mechanical Data
7.1 Package Thermal Resistance Characteristics
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Table 7-1 and Table 7-2 provide the thermal characteristics for the recommended package types used onthe TMS320C672x DSP.
Table 7-1. Thermal Characteristics for GDH/ZDH Package
AIR FLOWNO. °C/W
(m/s)
Two-Signal, Two-Plane, 101.5 x 114.5 x 1.6 mm , 2-oz Cu. EIA/JESD51-9 PCB1 R θ
JA
Thermal Resistance Junction to Ambient 25 02 R θ
JB
Thermal Resistance Junction to Board 14.5 03 R θ
JC
Thermal Resistance Junction to Top of Case 10 04Ψ
JB
Thermal Metric Junction to Board 14 05Ψ
JT
Thermal Metric Junction to Top of Case 0.39 0
Table 7-2. Thermal Characteristics for RFP Package
THERMAL PAD CONFIGURATION
AIRNO. °C/W FLOWVIATOP BOTTOM
(m/s)ARRAY
Two-Signal, Two-Plane, 76.2 x 76.2 mm PCB
(1) (2) (3)
1 R θ
JA
Thermal Resistance Junction to Ambient 10.6 x 10.6 mm 10.6 x 10.6 mm 6 x 6 20 07.5 x 7.5 mm 7.5 x 7.5 mm 5 x 5 22 02Ψ
JP
Thermal Metric Junction to Power Pad 10.6 x 10.6 mm 10.6 x 10.6 mm 6 x 6 0.39 0Double-Sided 76.2 x 76.2 mm PCB
(1) (2) (4)
3 R θ
JA
Thermal Resistance Junction to Ambient 10.6 x 10.6 mm 10.6 x 10.6 mm 6 x 6 49 010.6 x 10.6 mm 38.1 x 38.1 mm 6 x 6 27 010.6 x 10.6 mm 57.2 x 57 mm 6 x 6 22 010.6 x 10.6 mm 76.2 x 76.2 mm 6 x 6 20 04Ψ
JP
Thermal Metric Junction to Power Pad 10.6 x 10.6 mm 10.6 x 10.6 mm 6 x 6 0.39 0
(1) PCB modeled with 2 oz/ft
2
Top and Bottom Cu.(2) Package thermal pad must be properly soldered to top layer PCB thermal pad for both thermal and electrical performance. Thermal padis V
SS
.(3) Top layer thermal pad is connected through via array to both bottom layer thermal pad and internal V
SS
plane.(4) Top layer thermal pad is connected through via array to bottom layer thermal pad.
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7.2 Supplementary Information About the 144-Pin RFP PowerPAD™ Package
7.2.1 Standoff Height
Standoff Height
7.3 Packaging Information
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SPRS370E SEPTEMBER 2006 REVISED JULY 2008
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This section highlights a few important details about the 144-pin RFP PowerPAD™ package. TexasInstruments' PowerPAD Thermally Enhanced Package Technical Brief (literature number SLMA002)should be consulted before designing a PCB for this device.
As illustrated in Figure 7-1 , the standoff height specification for this device (between 0.050 mm and0.150 mm) is measured from the seating plane established by the three lowest package pins to the lowestpoint on the package body. Due to warpage, the lowest point on the package body is located in the centerof the package at the exposed thermal pad.
Using this definition of standoff height provides the correct result for determining the correct solder pastethickness. According to TI's PowerPAD Thermally Enhanced Package Technical Brief (literature numberSLMA002), the recommended range of solder paste thickness for this package is between 0.152 mm and0.178 mm.
Figure 7-1. Standoff Height Measurement on 144-Pin RFP Package
The following packaging information reflects the most current released data available for the designateddevice(s). This data is subject to change without notice and without revision of this document.
On the 144-pin RFP package, the actual size of the Thermal Pad is 5.4 mm ×5.4 mm.
110 Mechanical Data Submit Documentation Feedback
PACKAGE OPTION ADDENDUM
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Addendum-Page 1
PACKAGING INFORMATION
Orderable Device Status (1) Package Type Package
Drawing Pins Package Qty Eco Plan (2) Lead/
Ball Finish MSL Peak Temp (3) Samples
(Requires Login)
TMS320C6720BRFP200 ACTIVE HTQFP RFP 144 60 Green (RoHS
& no Sb/Br) CU NIPDAU Level-4-260C-72 HR
TMS320C6722BRFP200 ACTIVE HTQFP RFP 144 60 Green (RoHS
& no Sb/Br) CU NIPDAU Level-4-260C-72 HR
TMS320C6722BRFP250 ACTIVE HTQFP RFP 144 60 Green (RoHS
& no Sb/Br) CU NIPDAU Level-4-260C-72 HR
TMS320C6726BRFP266 ACTIVE HTQFP RFP 144 60 Green (RoHS
& no Sb/Br) CU NIPDAU Level-4-260C-72 HR
TMS320C6727BGDH300 ACTIVE BGA GDH 256 90 TBD SNPB Level-3-220C-168 HR
TMS320C6727BGDH350 ACTIVE BGA GDH 256 90 TBD SNPB Level-3-220C-168 HR
TMS320C6727BZDH275 ACTIVE BGA ZDH 256 90 Green (RoHS
& no Sb/Br) SNAGCU Level-3-260C-168 HR
TMS320C6727BZDH300 ACTIVE BGA ZDH 256 90 Green (RoHS
& no Sb/Br) SNAGCU Level-3-260C-168 HR
TMS320C6727BZDH350 ACTIVE BGA ZDH 256 90 Green (RoHS
& no Sb/Br) SNAGCU Level-3-260C-168 HR
TMSDC6722BRFPA225 ACTIVE HTQFP RFP 144 60 Green (RoHS
& no Sb/Br) CU NIPDAU Level-4-260C-72 HR
TMSDC6726BRFPA225 ACTIVE HTQFP RFP 144 60 Green (RoHS
& no Sb/Br) CU NIPDAU Level-4-260C-72 HR
TMSDC6727BGDHA250 ACTIVE BGA GDH 256 90 TBD SNPB Level-3-220C-168 HR
TMSDC6727BZDHA250 ACTIVE BGA ZDH 256 90 Green (RoHS
& no Sb/Br) SNAGCU Level-3-260C-168 HR
(1) The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
PACKAGE OPTION ADDENDUM
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Addendum-Page 2
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
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