ADSP-2195MKCA-160 データシートの表示（PDF） - Analog Devices

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ADSP-2195MKCA-160

DSP Microcomputer

Analog Devices 

35(/,0,1$5< 7(&+1,&$/ '$7$

September 2001 For current information contact Analog Devices at 800/262-5643

ADSP-2195

The functional modes selected by HPCR [7:6] are as follows

(assuming active high signal):

• ACK Mode—Acknowledge is active on strobes; HACK

goes high from the leading edge of the strobe to indicate

when the access can complete. After the Host samples the

HACK active, it can complete the access by removing the

strobe.The host port then removes the HACK.

• Ready Mode—Ready active on strobes, goes low to insert

wait state during the access.If the host port can not

complete the access, it de-asserts the HACK/READY

line. In this case, the Host has to extend the access by

keeping the strobe asserted. When the Host samples the

HACK asserted, it can then proceed and complete the

access by de-asserting the strobe.

While in Address Cycle Control (ACC) mode and the ACK

or Ready acknowledge modes, the HACK is returned active

for any address cycle.

Host Port Chip Selects

There are two chip-select signals associated with the Host

Port: HCMS and HCIOMS. The Host Chip Memory

Select (HCMS) lets the Host select the DSP and directly

access the DSP’s internal/external memory space or boot

memory space. The Host Chip I/O Memory Select

(HCIOMS) lets the Host select the DSP and directly access

the DSP’s internal I/O memory space.

Before starting a direct access, the Host configures Host

port interface registers, specifying the width of external data

bus (8- or 16-bit) and the target address page (in the IJPG

register). The DSP generates the needed memory select

signals during the access, based on the target address. The

Host port interface combines the data from one, two, or

three consecutive Host accesses (up to one 24-bit value) into

a single DMA bus access to prefetch Host direct reads or to

post direct writes. During assembly of larger words, the Host

port interface asserts ACK for each byte access that does

not start a read or complete a write. Otherwise, the Host

port interface asserts ACK when it has completed the

memory access successfully.

DSP Serial Ports (SPORTs)

The ADSP-2195 incorporates three complete synchronous

serial ports (SPORT0, SPORT1, and SPORT2) for serial

and multiprocessor communications. The SPORTs

support the following features:

• Bidirectional operation—each SPORT has independent

transmit and receive pins.

• Buffered (8-deep) transmit and receive ports—each port

has a data register for transferring data words to and from

other DSP components and shift registers for shifting data

in and out of the data registers.

• Clocking—each transmit and receive port can either use

an external serial clock (≤75 MHz) or generate its own,

in frequencies ranging from 1144 Hz to 75 MHz.

• Word length—each SPORT supports serial data words

from 3 to 16 bits in length transferred in Big Endian

(MSB) or Little Endian (LSB) format.

• Framing—each transmit and receive port can run with or

without frame sync signals for each data word. Frame sync

signals can be generated internally or externally, active

high or low, and with either of two pulsewidths and early

or late frame sync.

• Companding in hardware—each SPORT can perform

A-law or µ-law companding according to ITU recommen-

dation G.711. Companding can be selected on the

transmit and/or receive channel of the SPORT without

additional latencies.

• DMA operations with single-cycle overhead—each

SPORT can automatically receive and transmit multiple

buffers of memory data, one data word each DSP cycle.

Either the DSP’s core or a Host processor can link or chain

sequences of DMA transfers between a SPORT and

memory. The chained DMA can be dynamically allocated

and updated through the DMA descriptors (DMA

transfer parameters) that set up the chain.

• Interrupts—each transmit and receive port generates an

interrupt upon completing the transfer of a data word or

after transferring an entire data buffer or buffers through

DMA.

• Multichannel capability—each SPORT supports the

H.100 standard.

Serial Peripheral Interface (SPI) Ports

The DSP has two SPI-compatible ports that enable the DSP

to communicate with multiple SPI-compatible devices.

These ports are multiplexed with SPORT2, so either

SPORT2 or the SPI ports are active, depending on the state

of the OPMODE pin during hardware reset.

The SPI interface uses three pins for transferring data: two

data pins (Master Output-Slave Input, MOSIx, and Master

Input-Slave Output, MISOx) and a clock pin (Serial Clock,

SCKx). Two SPI chip select input pins (SPISSx) let other

SPI devices select the DSP, and fourteen SPI chip select

output pins (SPIxSEL7–1) let the DSP select other SPI

devices. The SPI select pins are reconfigured Programmable

Flag pins. Using these pins, the SPI ports provide a full

duplex, synchronous serial interface, which supports both

master and slave modes and multimaster environments.

Each SPI port’s baud rate and clock phase/polarities are

programmable (see Figure 4), and each has an integrated

DMA controller, configurable to support both transmit and

receive data streams. The SPI’s DMA controller can only

service unidirectional accesses at any given time.

SPI Clock Rate = -2----×-----S-H---P--C--I--B-L----KA-----U-----D---

Figure 4. SPI Clock Rate Calculation

REV. PrA

This information applies to a product under development. Its characteristics and specifications are subject to change with-

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out notice. Analog Devices assumes no obligation regarding future manufacturing unless otherwise agreed to in writing.

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