MT9160 Datasheet, PDF(10/28 Page) Mitel Networks Corporation – ISO2-CMOS 5 Volt Multi-Featured Codec (MFC)

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MT9160 Datasheet, PDF (10/28 Pages) Mitel Networks Corporation – ISO2-CMOS 5 Volt Multi-Featured Codec (MFC)

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MT9160

Preliminary Information

An interrupt output is provided (IRQ) to synchronize

microprocessor access to the D-Channel register

during valid ST-BUS periods only. IRQ will occur

every fourth (eighth in 8 kb/s mode) ST-BUS frame

at the beginning of the third (second in 8 kb/s mode)

ST-BUS bit cell period. The interrupt will be removed

following a microprocessor Read or Write of Address

04 hex or upon encountering the following framesâs

FP input, whichever occurs first. To ensure

D-Channel data integrity, microport read/write

access to Address 04 hex must occur before the

following frame pulse. See Figure 8b for timing.

8 kb/s operation expands the interrupt to every eight

frames and processes data one-bit-per-frame.

D-Channel register data is mapped according to

Figure 8c.

CEn - C-Channel

Channel 1 conveys the control/status information for

the Layer 1 transceiver. C-Channel data is

transferred MSB first on the ST-BUS by the MT9160.

The full 64 kb/s bandwidth is available and is

assigned according to which transceiver is being

used. Consult the data sheet for the selected

transceiver for its C-Channel bit definitions and order

of bit transfer.

When CEN is high, data written to the C-Channel

significant bit first, on DSTo. On power-up reset

(PWRST) or software reset (Rst, address 03h) all

C-Channel bits default to logic high. Receive

C-Channel data (DSTi) is always routed to the read

When low, data transmission is halted and this

timeslot is tri-stated on DSTo.

B1-Channel and B2-Channel

Channels 2 and 3 are the B1 and B2 channels,

respectively. B-channel PCM associated with the

Filter/Codec and transducer audio paths is selected

on an independent basis for the transmit and receive

paths. TxBSel and RxBSel (Control Register 1,

address 03h) are used for this purpose.

If no valid transmit path has been selected then the

timeslot output on DSTo is tri-stated (see PDFDI and

PDDR control bits, Control Register 1 address 03h).

SSI Mode

The SSI BUS consists of input and output serial data

streams named Din and Dout respectively, a Clock

input signal (CLOCKin), and a framing strobe input

(STB). The frame strobe must be synchronous with,

and eight cycles of, the bit clock. A 4.096 MHz

master clock is also required for SSI operation if the

bit clock is less than 512 kHz. The timing

requirements for SSI are shown in Figures 12 & 13.

In SSI mode the MT9160 supports only B-Channel

operation. The internal C and D Channel registers

used in ST-BUS mode are not functional for SSI

operation. The control bits TxBSel and RxBSel, as

described in the ST-BUS section, are ignored since

the B-Channel timeslot is defined by the input STB

strobe. Hence, in SSI mode transmit and receive

B-Channel data are always in the channel defined by

the STB input.

The data strobe input STB determines the 8-bit

timeslot used by the device for both transmit and

receive data. This is an active high signal with an 8

kHz repetition rate.

SSI operation is separated into two categories based

upon the data rate of the available bit clock. If the bit

clock is 512 kHz or greater then it is used directly by

the internal MT9160 functions allowing synchronous

operation. If the available bit clock is 128 kHz or 256

kHz, then a 4096 kHz master clock is required to

derive clocks for the internal MT9160 functions.

Applications where Bit Clock (BCL) is below 512 kHz

are designated as asynchronous. The MT9160 will

re-align its internal clocks to allow operation when

the external master and bit clocks are asynchronous.

Control bits CSL2, CSL1 and CSL0 in Control

rates.

For synchronous operation data is sampled, from

Din, on the falling edge of BCL during the time slot

defined by the STB input. Data is made available, on

Dout, on the rising edge of BCL during the time slot

defined by the STB input. Dout is tri-stated at all

times when STB is not true. If STB is valid but PDFDI

and PDDR are not true, then quiet code will be

transmitted on Dout during the valid strobe period.

There is no frame delay through the FDI circuit for

synchronous operation.

For asynchronous operation Dout and Din are as

defined for synchronous operation except that the

allowed output jitter on Dout is larger. This is due to

the resynchronization circuitry activity and will not

7-86

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