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SAA7372

Digital servo processor and Compact Disc decoder (CD7)

Philips Electronics 

Philips Semiconductors

Digital servo processor and Compact Disc

decoder (CD7)

Product specification

SAA7372

7.12 The VIA interface

The SAA7372 has five pins that can be reconfigured for different applications (see Table 8).

Table 8 Pin applications

PIN NAME

PIN

NUMBER

V1

62

V2

63

V3

42

V4

41

V5

40

TYPE

input

input

output

output

output

CONTROL

REGISTER

ADDRESS

1100

−

−

1100

−

−

1101

−

−

−

1101

−

−

CONTROL

REGISTER

DATA

xxx1

xxx0

−

xx0x

x01x

x11x

0000

xx01

xx10

xx11

01xx

10xx

11xx

FUNCTION

external off-track signal input

internal off-track signal used, input may be read

via decoder status bit; selected via register 2

input may be read via decoder status bit;

selected via register 2

KILL output for right channel

output = 0

output = 1

4-line motor drive (using V4 and V5)

Q-to-W subcode output

output = 0

output = 1

de-emphasis output (active HIGH)

output = 0

output = 1

7.13 Spindle motor control

7.13.1 MOTOR OUTPUT MODES

The spindle motor speed is controlled by a fully integrated

digital servo. Address information from the internal

±8 frame FIFO and disc speed information are used to

calculate the motor control output signals. Several output

modes, selected by register 6, are supported:

• Pulse density, 2-line (true complement output),

(1 × n) MHz sample frequency

• PWM output, 2-line, (22.05 × n) kHz modulation

frequency

• PWM output, 4-line, (22.05 × n) kHz modulation

frequency

• CDV motor mode.

7.13.1.1 Pulse density output mode

In the pulse density mode the motor output pin (MOTO1)

is the pulse density modulated motor output signal. A 50%

duty factor corresponds with the motor not actuated,

higher duty factors mean acceleration, lower mean

braking. In this mode, the MOTO2 signal is the inverse of

the MOTO1 signal. Both signals change state only on the

edges of a (1 × n) MHz internal clock signal. Possible

application diagrams are illustrated in Fig.13.

7.13.1.2 PWM output mode (2-line)

In the PWM mode the motor acceleration signal is put in

pulse-width modulation form on the MOTO1 output. The

motor braking signal is pulse-width modulated on the

MOTO2 output. The timing is illustrated in Fig.14. A typical

application diagram is illustrated in Fig.15.

1998 Feb 26

20

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