mc145480vf Freescale Semiconductor, Inc, mc145480vf Datasheet - Page 8

mc145480vf

Manufacturer Part Number

mc145480vf

Description

Mc145480 5 V Pcm Codec-filter

Manufacturer

Freescale Semiconductor, Inc

Datasheet

1.MC145480VF.pdf (24 pages)

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FSR pin controls whether the B1 channel or the B2 channel

is used for both transmit and receive PCM data word trans-

fers. When the FSR pin is low, the transmit and receive PCM

words are transferred in the B1 channel, and for FSR high

the B2 channel is selected. The start of the B2 channel is ten

IDL CLK cycles after the start of the B1 channel.

synchronization signal. The signal at this pin is nominally

high for one cycle of the IDL Clock signal and is rising edge

aligned with the IDL Clock signal. (Refer to Figure 4 and the

IDL Timing specifications for more details.) This event identi-

fies the beginning of the IDL frame. The frequency of the IDL

Sync signal is 8 kHz. The rising edge of the IDL SYNC (FST)

should be aligned approximately with the rising edge of

MCLK. MCLK must be one of the clock frequencies specified

in the Digital Switching Characteristics table, and is typically

tied to IDL CLK (BCLKT).

data clock. All IDL PCM transfers and data control sequenc-

ing are controlled by this clock following the IDL SYNC. This

pin accepts an IDL data clock frequency of 256 kHz to 4.096

MHz.

data word. Data bits are output for the B1 channel on se-

quential rising edges of the IDL CLK signal beginning after

the IDL SYNC pulse. If the B2 channel is selected, then the

PCM word transfer starts on the eleventh IDL CLK rising

edge after the IDL SYNC pulse. The IDL TX pin will remain

low impedance for the duration of the PCM word until the

LSB after the falling edge of IDL CLK. The IDL TX pin will re-

main in a high impedance state when not outputting PCM

data or when a valid IDL Sync signal is missing.

data word. Data bits are input for the B1 channel on sequen-

tial falling edges of the IDL CLK signal beginning after the

IDL SYNC pulse. If the B2 channel is selected, then the PCM

word is latched in starting on the eleventh IDL CLK falling

edge after the IDL SYNC pulse.

General Circuit Interface (GCI)

standard synchronous 2B+D ISDN timing interface modes

with which this device is compatible. In the GCI mode, the

device can communicate in either of the two 64 kbps B–

channels. (Refer to Figure 2d for sample timing.) The GCI

mode is selected when the BCLKR pin is held low for two or

more FST (FSC) rising edges. The digital pins that control

the transmit and receive PCM word transfers are repro-

grammed to accommodate this mode. The pins affected are

FST, FSR, BCLKT, DT, and DR. The GCI Interface consists

of four pins: FSC (FST), DCL (BCLKT), D out (DT), and D in

(DR). The GCI interface mode provides access to both the

transmit and receive PCM data words with common control

clocks of FSC (frame synchronization clock) and DCL (data

clock). In this mode, the FSR pin controls whether the B1

channel or the B2 channel is used for both transmit and re-

ceive PCM data word transfers. When the FSR pin is low, the

transmit and receive PCM words are transferred in the B1

channel, and for FSR high the B2 channel is selected. The

start of the B2 channel is 16 DCL cycles after the start of the

B1 channel.

MC145480

The IDL SYNC (FST, Pin 14) is the input for the IDL frame

The General Circuit Interface (GCI) is the second of two

The IDL TX (DT, Pin 13) is the output for the transmit PCM

The IDL RX (DR, Pin 8) is the input for the receive PCM

The IDL CLK (BCLKT, Pin 12) is the input for the PCM

chronization signal. The signal at this pin is nominally rising

edge aligned with the DCL clock signal. (Refer to Figure 6

and the GCI Timing specifications for more details.) This

event identifies the beginning of the GCI frame. The frequen-

cy of the FSC synchronization signal is 8 kHz. The rising

edge of the FSC (FST) should be aligned approximately with

the rising edge of MCLK. MCLK must be one of the clock fre-

quencies specified in the Digital Switching Characteristics

table, and is typically tied to DCL (BCLKT).

controls the PCM data transfers. The clock applied at the

DCL input is twice the actual PCM data rate. The GCI frame

begins with the logical AND of the FSC with the DCL. This

event initiates the PCM data word transfers for both transmit

and receive. This pin accepts a GCI data clock frequency of

512 kHz to 6.176 MHz for PCM data rates of 256 kHz to

3.088 MHz.

PCM data word. Data bits are output for the B1 channel on

alternate rising edges of the DCL clock signal, beginning with

the FSC pulse. If the B2 channel is selected, then the PCM

word transfer starts on the seventeenth DCL rising edge after

the FSC rising edge. The D out pin will remain low impedance

for 15–1/2 DCL clock cycles. The D out pin becomes high

impedance after the second falling edge of the DCL clock

during the LSB of the PCM word. The D out pin will remain in

a high–impedance state when not outputting PCM data or

when a valid FSC signal is missing.

word. Data bits are latched in for the B1 channel on alternate

rising edges of the DCL clock signal, beginning with the se-

cond DCL clock after the rising edge of the FSC pulse. If the

B2 channel is selected then the PCM word is latched in start-

ing on the eighteenth DCL rising edge after the FSC rising

edge.

VLSI technology to implement the complex analog signal

processing functions of a PCM Codec–Filter. The fully–differ-

ential analog circuit design techniques used for this device

result in superior performance for the switched capacitor fil-

ters, the analog–to–digital converter (ADC) and the digital–

to–analog converter (DAC). Special attention was given to

the design of this device to reduce the sensitivities of noise,

including power supply rejection and susceptibility to radio

frequency noise. This special attention to design includes a

fifth order low–pass filter, followed by a third order high–pass

filter whose output is converted to a digital signal with greater

than 75 dB of dynamic range, all operating on a single 5 V

power supply. This results in a Mu–Law LSB size for small

audio signals of about 386 V. The typical idle channel noise

level of this device is less than one LSB. In addition to the

dynamic range of the codec–filter function of this device, the

input gain–setting op amp has the capability of greater than

35 dB of gain intended for an electret microphone interface.

due to the large dynamic range and the noisy nature of the

environment for this device (digital switches, radio tele-

phones, DSP front–end, etc.) special care must be taken to

assure optimum analog transmission performance.

The FSC (FST, Pin 14) is the input for the GCI frame syn-

The DCL (BCLKT, Pin 12) is the input for the clock that

The GCI D out (DT, Pin 13) is the output for the transmit

The D in (DR, Pin 8) is the input for the receive PCM data

The MC145480 is manufactured using high–speed CMOS

This device was designed for ease of implementation, but

PRINTED CIRCUIT BOARD LAYOUT

CONSIDERATIONS

MOTOROLA

mc145480vf Freescale Semiconductor, Inc, mc145480vf Datasheet - Page 8

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