Philips SAA7376GP-M1, SAA7376GP-M1-C Datasheet

DATA SH EET

Product specifications
Supersedes data of 1995 Nov 24
File under Integrated Circuits, IC01

1998 Feb 26

INTEGRATED CIRCUITS

SAA7376

Digital servo processor and
Compact Disc decoder (CD7)

1998 Feb 26 2

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

CONTENTS

1 FEATURES
2 GENERAL DESCRIPTION
3 QUICK REFERENCE DATA
4 ORDERING INFORMATION
5 BLOCK DIAGRAM
6 PINNING
7 FUNCTIONAL DESCRIPTION

7.1 Decoder part

7.1.1 Principle operational modes of the decoder

7.1.2 Crystal frequency selection

7.1.3 Standby modes

7.2 Crystal oscillator

7.3 Data slicer and clock regenerator

7.4 Demodulator

7.4.1 Frame sync protection

7.4.2 EFM demodulation

7.5 Subcode data processing

7.5.1 Q-channel processing

7.5.2 EIAJ 3 and 4-wire subcode (CD graphics)
interfaces

7.5.3 V4 subcode interface

7.6 FIFO and error corrector

7.6.1 Flags output (CFLG)

7.6.2 C2FAIL

7.7 Audio functions

7.7.1 De-emphasis and phase linearity

7.7.2 Digital oversampling filter

7.7.3 Concealment

7.7.4 Mute, full scale, attenuation and fade

7.7.5 Peak detector

7.8 DAC interface

7.9 EBU interface

7.9.1 Format

7.10 KILL circuit

7.11 The VIA interface

7.12 Spindle motor control

7.12.1 Motor output modes

7.12.2 Spindle motor operating modes

7.12.3 Loop characteristics

7.12.4 FIFO overflow

7.13 Servo part

7.13.1 Diode signal processing

7.13.2 Signal conditioning

7.13.3 Focus servo system

7.13.4 Radial servo system

7.13.5 Off-track counting

7.13.6 Defect detection

7.13.7 Off-track detection

7.13.8 high-level features

7.13.9 Driver interface

7.13.10 Laser interface

7.13.11 Radial shock detector

7.14 Microcontroller interface

7.14.1 Microprocessor interface (4-wire bus mode)

7.14.2 Microcontroller interface (I2C-bus mode)

7.14.3 Summary of functions controlled by registers
0toF

7.14.4 Summary of servo commands

7.14.5 Summary of servo command parameters

8 LIMITING VALUES
9 OPERATING CHARACTERISTICS
10 OPERATING CHARACTERISTICS

(SUBCODE INTERFACE TIMING)

11 OPERATING CHARACTERISTICS (I2S-BUS

TIMING)

12 OPERATING CHARACTERISTICS

(MICROCONTROLLER INTERFACE TIMING)

13 APPLICATION INFORMATION
14 PACKAGE OUTLINE
15 SOLDERING

15.1 Introduction

15.2 Reflow soldering

15.3 Wave soldering

15.4 Repairing soldered joints

16 DEFINITIONS
17 LIFE SUPPORT APPLICATIONS
18 PURCHASE OF PHILIPS I2C COMPONENTS

1998 Feb 26 3

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

1 FEATURES

• Single-speed mode

• Full error correction strategy, t = 2 and e = 4

• Full CD graphics interface

• All standard decoder functions implemented digitally on

chip

• FIFO overflow concealment for rotational shock
resistance

• Digital audio interface (EBU), audio only

• 2 and 4 times oversampling integrated digital filter,

including f

s

mode

• Audio data peak level detection

• Kill interface for DAC deactivation during digital silence

• All TDA1301 (DSIC2) digital servo functions, plus extra

high-level functions

• Low focus noise

• Improved playability on ABEX TCD-721R, TCD-725 and

TCD-714 discs

• Automatic closed loop gain control available for focus
and radial loops

• Pulsed sledge support

• Microcontroller loading LOW

• High-level servo control option

• High-level mechanism monitor

• Communication may be via TDA1301/SAA7345

compatible bus or I2C-bus

• On-chip clock multiplier allows the use of 8.4672 MHz
crystal.

2 GENERAL DESCRIPTION

The SAA7376 is a single chip combining the functions of a
CD decoder IC and digital servo IC. The decoder part is
based on the SAA7345 (CD6) with an improved error
correction strategy. The servo part is based on the
TDA1301T (DSIC2) with improvements incorporated,
extra features have also been added.

Supply of this Compact Disc IC does not convey an implied
license under any patent right to use this IC in any
Compact Disc application.

3 QUICK REFERENCE DATA

4 ORDERING INFORMATION

SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT

V

DD

supply voltage 3.4 5.0 5.5 V

I

DD

supply current − 49 − mA

f

xtal

crystal frequency 8 8.4672 35 MHz

T

amb

operating ambient temperature −10 − +70 °C

T

stg

storage temperature −55 − +125 °C

TYPE

NUMBER

PACKAGE

NAME DESCRIPTION VERSION

SAA7376 QFP64 plastic quad flat package; 64 leads (lead length 1.6 mm);

body 14 × 14 × 2.7 mm

SOT393-1

1998 Feb 26 4

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

handbook, full pagewidth

DECODER

MICRO-

CONTROLLER

INTERFACE

VERSATILE PINS

INTERFACE

SUBCODE

PROCESSOR

KILL

PEAK

DETECT

SERIAL DATA

INTERFACE

TIMING

TEST

ADC

V

ref

GENERATOR

FRONT END

DIGITAL

PLL

MOTOR

CONTROL

AUDIO

PROCESSOR

EBU

INTERFACE

ERROR

CORRECTOR

MICROCONTROLLER

INTERFACE

PRE-

PROCESSING

CONTROL

FUNCTION

CONTROL

PART

EFM

DEMODULATOR

SRAM

RAM

ADDRESSER

OUTPUT
STAGES

FLAGS

6

8
9

11

52
51
53
54

15
17
14
18

20
23
29

13
21
22
24
25
50

35
36
38
37

58

57

62 63 42 41 40 43

3 4 5 7 10 1 12 16 2 19 32 39 49 56 30 47 59

26
27
28

64

33
34

61

60

31

48
46
45
44

V

RL

V

RH

I

ref

R2

SCL
SDA
RAB
SILD

HFIN

HFREF

ISLICE

TEST1
TEST2
TEST3

SELPLL

CRIN

CROUT

CL16
CL11

CL4

SBSY
SFSY

SUB
RCK

STATUS

RESET

R1

D1 D2 D3 D4

I

refT

V

SSA1VSSA3VDDA2VSSD2VSSD4VDDD2(P)

V

SSA2VDDA1VSSD1VSSD3VDDD1(P)VDDD3(C)

V1 V2 V3 V4 V5 KILL

TEST4

DATA

WCLK

SCLK

DOBM

C2FAIL

MOTO2

MOTO1

LDON

SL

FO

RA

CFLG

SAA7376

MGD043

5 BLOCK DIAGRAM

Fig.1 Block diagram.

1998 Feb 26 5

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

6 PINNING

SYMBOL PIN DESCRIPTION

V

SSA1

1

(1)

analog ground 1

V

DDA1

2

(1)

analog supply voltage 1
D1 3 unipolar current input (central diode signal input)
D2 4 unipolar current input (central diode signal input)
D3 5 unipolar current input (central diode signal input)
V

RL

6 reference voltage input for ADC
D4 7 unipolar current input (central diode signal input)
R1 8 unipolar current input (satellite diode signal input)
R2 9 unipolar current input (satellite diode signal input)
I

refT

10 current reference output for ADC calibration

V

RH

11 reference voltage output from ADC

V

SSA2

12

(1)

analog ground 2
SELPLL 13 selects whether internal clock multiplier PLL is used
ISLICE 14 current feedback output from data slicer
HFIN 15 comparator signal input
V

SSA3

16

(1)

analog ground 3
HFREF 17 comparator common mode input
I

ref

18 reference current output pin (nominally 0.5VDD)

V

DDA2

19

(1)

analog supply voltage 2
TEST1 20 test control input 1; this pin should be tied LOW
CRIN 21 crystal/resonator input
CROUT 22 crystal/resonator output
TEST2 23 test control input 2; this pin should be tied LOW
CL16 24 16.9344 MHz system clock output
CL11 25 11.2896 or 5.6448 MHz clock output (3-state)
RA 26 radial actuator output
FO 27 focus actuator output
SL 28 sledge control output
TEST3 29 test control input 3; this pin should be tied LOW
V

DDD1(P)

30

(1)

digital supply voltage 1 for periphery
DOBM 31 bi-phase mark output (externally buffered; 3-state)
V

SSD1

32

(1)

digital ground 1
MOTO1 33 motor output 1; versatile (3-state)
MOTO2 34 motor output 2; versatile (3-state)
SBSY 35 subcode block sync output (3-state)
SFSY 36 subcode frame sync output (3-state)
RCK 37 subcode clock input
SUB 38 P-to-W subcode output bits (3-state)
V

SSD2

39

(1)

digital ground 2
V5 40 versatile output pin 5

1998 Feb 26 6

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

Note

1. All supply pins must be connected to the same external power supply voltage.

V4 41 versatile output pin 4
V3 42 versatile output pin 3 (open-drain)
KILL 43 kill output (programmable; open-drain)
TEST4 44 test output pin; this pin should be left unconnected
DATA 45 serial data output (3-state)
WCLK 46 word clock output (3-state)
V

DDD2(P)

47

(1)

digital supply voltage 2 for periphery
SCLK 48 serial bit clock output (3-state)
V

SSD3

49

(1)

digital ground 3
CL4 50 4.2336 MHz microcontroller clock output
SDA 51 microcontroller interface data I/O line (open-drain output)
SCL 52 microcontroller interface clock line input
RAB 53 microcontroller interface R/

W and load control line input (4-wire bus mode)

SILD 54 microcontroller interface

R/W and load control line input (4-wire-bus mode)
n.c. 55 not connected
V

SSD4

56

(1)

digital ground 4
RESET 57 power-on reset input (active LOW)
STATUS 58 servo interrupt request line/decoder status register output (open-drain)
V

DDD3(C)

59

(1)

digital supply voltage 3 for core
C2FAIL 60 indication of correction failure output (open-drain)
CFLG 61 correction flag output (open-drain)
V1 62 versatile input pin 1
V2 63 versatile input pin 2
LDON 64 laser drive on output (open-drain)

SYMBOL PIN DESCRIPTION

1998 Feb 26 7

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

Fig.2 Pin configuration.

handbook, full pagewidth

SAA7376

MGD042

1
2
3
4
5
6
7
8

9
10
11
12
13
14
15
16

V

SSA1

V

DDA1

D1
D2
D3

V

RL
D4

R1
R2

I

refT

V

RH

V

SSA2

SELPLL

ISLICE

HFIN

V

SSA3

48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33

SCLK
V

DDD2(P)

WCLK
DATA
TEST4
KILL
V3
V4
V5
V

SSD2

SUB
RCK
SFSY
SBSY
MOTO2
MOTO1

17

18

19

20

21

22

23

24

25

26

27

28

29

30

31

32

HFREF

I

ref

V

DDA2

TEST1

CRIN

CROUT

TEST2

CL16

CL11

RA

FO

SL

TEST3

V

DDD1(P)

DOBM

V

SSD1

LDONV2V1

CFLG

C2FAIL

V

DDD3(C)

STATUS

RESET

V

SSD4

n.c.

SILD

RAB

SCL

SDA

CL4

V

SSD3

64

63

62

61

60

59

58

57

56

55

54

53

52

51

50

49

1998 Feb 26 8

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

7 FUNCTIONAL DESCRIPTION

7.1 Decoder part

7.1.1 P

RINCIPLE OPERATIONAL MODES OF THE DECODER

The decoding part operates at single-speed and supports
a full audio specification.

A simplified data flow through the decoder part is
illustrated in Fig.6.

7.1.2 C

RYSTAL FREQUENCY SELECTION

The SAA7376, which has an internal phase-locked loop
clock multiplier, can be used with 33.8688, 16.9344 or

8.4672 MHz crystal frequencies by setting register B and
SELPLL as shown in Table 1. The internal clock multiplier,
controlled by SELPLL, should only be used if a

8.4672 MHz crystal, ceramic resonator or external clock is
present. It should be noted that the CL11 output is a

5.6448 MHz clock if a 16.9344 MHz external clock is used.

Table 1 Crystal frequency selection

7.1.3 S

TANDBY MODES

The SAA7376 may be placed in two standby modes
selected by register B (it should be noted that the device
core is still active)

Standby 1: “CD-STOP” mode. Most I/O functions are
switched off.

Standby 2: “CD-PAUSE” mode. Audio output features
are switched off, but the motor loop, the motor output
and the subcode interfaces remain active. This is also
called a “Hot Pause”.

In the standby modes the various pins will have the
following values;

MOTO1 and MOTO2: put in high-impedance, PWM
mode (standby 1 and RESET, operating in standby 2).
Put in high-impedance, PDM mode (standby 1 and
RESET, operating in standby 2).

SCL, SDA, SILD and RAB: no interaction. Normal
operation continues.

SCLK, WCLK, DATA, CL11 and DOBM: 3-state in both
standby modes. Normal operation continues after reset.

REGISTER B SELPLL

CRYSTAL FREQUENCY

(MHz)

00xx 0 33.8688
00xx 1 8.4672
01xx 0 16.9344

CRIN, CROUT, CL16 and CL4: no interaction. Normal
operation continues.

V1, V2, V3, V4, V5, CFLG and C2FAIL: no interaction.
Normal operation continues.

7.2 Crystal oscillator

The crystal oscillator is a conventional 2 pin design
operating between 8 and 35 MHz. This oscillator is
capable of operating with ceramic resonators and also with
both fundamental and third overtone crystals. External
components should be used to suppress the fundamental
output of the third overtone crystals as shown in Figs 3
and 4. Typical oscillation frequencies required are 8.4672,

16.9344 or 33.8688 MHz depending on the internal clock
settings used and whether or not the clock multiplier is
enabled.

Fig.3 8.4672 MHz fundamental configuration.

8.4672 MHz

CRINCROUT

SAA7376

22 pF22 pF

330 Ω

100 kΩ

OSCILLATOR

MGD041

Fig.4 33.8688 MHz overtone configuration.

OSCILLATOR

33.8688 MHz

CRIN

CROUT

SAA7376

3.3 µH

1 nF10 pF10 pF

330 Ω

100 kΩ

MGD040

1998 Feb 26 9

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

7.3 Data slicer and clock regenerator

The SAA7376 has an integrated slice level comparator
which can be clocked by the crystal frequency clock, or
8 times the crystal frequency clock (if SELPLL is set HIGH
while using an 8.4672 MHz crystal, and register 4 is set
to 0xxx). The slice level is controlled by an internal current
source applied to an external capacitor under the control
of the Digital Phase-Locked Loop (DPLL).

Regeneration of the bit clock is achieved with an internal
fully digital PLL. No external components are required and
the bit clock is not output. The PLL has two registers
(8 and 9) for selecting bandwidth and equalization.

For certain applications an off-track input is necessary.
This is internally connected from the servo part (its polarity
can be changed by the foc_parm1 parameter), but may be
input via the V1 pin if selected by register C. If this flag is
HIGH, the SAA7376 will assume that its servo part is
following on the wrong track and will flag all incoming HF
data as incorrect.

7.4 Demodulator

7.4.1 F

RAME SYNC PROTECTION

A double timing system is used to protect the demodulator
from erroneous sync patterns in the serial data.

The master counter is only reset if:

• A sync coincidence detected; sync pattern occurs
588 ±1 EFM clocks after the previous sync pattern

• A new sync pattern is detected within ±6 EFM clocks of
its expected position.

The sync coincidence signal is also used to generate the
PLL lock signal, which is active HIGH after 1 sync
coincidence found, and reset LOW if, during 61
consecutive frames, no sync coincidence is found. The
PLL lock signal can be accessed via the SDA or STATUS
pins selected by register 2 and 7.

Also incorporated in the demodulator is a Run Length 2
(RL2) correction circuit. Every symbol detected as RL2 will
be pushed back to RL3. To do this, the phase error of both
edges of the RL2 symbol are compared and the correction
is executed at the side with the highest error probability.

7.4.2 EFM DEMODULATION

The 14-bit EFM data and subcode words are decoded into
8-bit symbols.

Fig.5 Data slicer showing typical application components.

47 pF

22 nF

2.2 kΩ

HFIN

HFREF

I

ref

ISLICE

22 kΩ

100 nF

2.2 nF

HF

input

crystal

clock

DQ

DPLL

1/2V

DD

V

SSA

V

SS

V

SSA

MGA368 - 1

V

DD

100 µA

100 µA

1998 Feb 26 10

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc

decoder (CD7)

SAA7376

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handbook, full pagewidth

SUBCODE

PROCESSOR

DIGITAL PLL AND

DEMODULATOR

FIFO

ERROR

CORRECTOR

FADE/MUTE/

INTERPOLATE

DIGITAL

FILTER

PHASE

COMPENSATION

DE-EMPHASIS

FILTER

KILL

1
0

1
0

1
0

1
0

I2S-BUS

INTERFACE

SCLK
WCLK
DATA

reg 3

reg C

reg 3

reg F

reg A

0 : reg D = xx01

V4 SUBCODE

INTERFACE

MICROCONTROLLER

INTERFACE

CD GRAPHICS

INTERFACE

EBU

INTERFACE

SBSY
SFSY
SUB

DOBM

V4

SDA

output from

data slicer

1 : reg 3 = xx10

(1fs mode)

0 : reg 3 ≠ xx10

1 : no pre-emphasis detected
OR reg D = 01xx (de-emphasis signal at V5)
0 : pre-emphasis detected
AND reg D ≠ 01xx

KILL
V3

MGD039

Fig.6 Simplified data flow of decoder functions.

1998 Feb 26 11

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

7.5 Subcode data processing

7.5.1 Q-

CHANNEL PROCESSING

The 96-bit Q-channel word is accumulated in an internal
buffer. The last 16 bits are used internally to perform a
Cyclic Redundancy Check (CRC). If the data is good, the
SUBQREADY-I signal will go LOW. SUBQREADY-I can
be read via the SDA or STATUS pins, selected via
register 2. Good Q-channel data may be read from SDA.

7.5.2 EIAJ 3

AND 4-WIRE SUBCODE (CD GRAPHICS)

INTERFACES

Data from all the subcode channels (P-to-W) may be read
via the subcode interface, which conforms to
EIAJ CP-2401. The interface is enabled and configured as
either a 3-wire or 4-wire interface via register F. The
subcode interface output formats are illustrated in Fig.7,
where the RCK signal is supplied by another device such
as a CD graphics decoder.

7.5.3 V4

SUBCODE INTERFACE

Data of subcode channels, Q-to-W, may be read via pin V4
if selected via register D. The format is similar to RS232
and is illustrated in Fig.8. The subcode sync word is
formed by a pause of 200 µs minimum. Each subcode byte
starts with a logic 1 followed by 7 bits (Q-to-W). The gap
between bytes is variable between 11.3 µs and 90 µs.

The subcode data is also available in the EBU output
(DOBM) in a similar format.

Fig.7 EIAJ subcode (CD graphics) interface format.

handbook, full pagewidth

SBSY

SFSY

RCK

SUB

SFSY

RCK

SUB

SFSY

RCK

SUB

EIAJ 4-wire subcode interface

EIAJ 3-wire subcode interface

SF0 SF1

SF2 SF3 SF97 SF0 SF1

P-W P-W P-W

P-W P-W P-W

PQRSTUVW

MBG410

SF0 SF1 SF2 SF3 SF97 SF0 SF1

1998 Feb 26 12

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

Fig.8 Subcode format and timing on pin V4.

W96 1QRSTUVW 1Q

200 µs

min

11.3
µs

11.3 µs min
90 µs max

MGD038

7.6 FIFO and error corrector

The SAA7376 has a ±8 frame FIFO. The error corrector is
a t = 2, e = 4 type, with error corrections on both C1
(32 symbol) and C2 (28 symbol) frames. Four symbols are
used from each frame as parity symbols. This error
corrector can correct up to two errors on the C1 level and
up to four errors on the C2 level.

The error corrector also contains a flag processor. Flags
are assigned to symbols when the error corrector cannot
ascertain if the symbols are definitely good. C1 generates
output flags which are read after (de-interleaving) by C2,
to help in the generation of C2 output flags.

The C2 output flags are used by the interpolator for
concealment of uncorrectable errors. They are also output
via the EBU signal (DOBM).

7.6.1 FLAGS OUTPUT (CFLG)
The flags output pin CFLG (open-drain) shows the status

of the error corrector and interpolator and is updated every
frame (7.35 kHz). In the SAA7376 chip a 1-bit flag is
present on the CFLG pin as illustrated in Fig.9. This signal
shows the status of the error corrector and interpolator.

The first flag bit, F1, is the absolute time sync signal, the
FIFO-passed subcode sync and relates the position of the
subcode sync to the audio data (DAC output). This flag
may also be used in a super FIFO or in the synchronization
of different players. The output flags can be made
available at bit 4 of the EBU data format (LSB of the 24-bit
data word), if selected by register A.

Fig.9 Flag output timing diagram.

handbook, full pagewidth

F1 F2 F3 F4 F5 F6 F7 F8 F1F8

11.3
µs

33.9 µs

33.9 µs

MGD037

1998 Feb 26 13

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

Table 2 Output flags

F1 F2 F3 F4 F5 F6 F7 F8 DESCRIPTION

0xxxxxxxno absolute time sync
1xxxxxxxabsolute time sync
x00xxxxxC1 frame contained no errors
x01xxxxxC1 frame contained 1 error
x10xxxxxC1 frame contained 2 errors
x11xxxxxC1 frame uncorrectable
x x x 0 0 x x 0 C2 frame contained no errors
x x x 0 0 x x 1 C2 frame contained 1 error
x x x 0 1 x x 0 C2 frame contained 2 errors
x x x 0 1 x x 1 C2 frame contained 3 errors
x x x 1 0 x x 0 C2 frame contained 4 errors
x x x 1 1 x x 1 C2 frame uncorrectable
xxxxx00xno interpolations
xxxxx01xat least one 1 sample interpolation
xxxxx10xat least one hold and no interpolations
xxxxx11xat least one hold and one 1 sample interpolation

7.6.2 C2FAIL
The C2FAIL pin indicates that invalid data has occurred on

the I2S-bus interface. However, due to the structure of the
corrector it is impossible to determine which byte has
failed. C2FAIL will go LOW for 140 µs when invalid data is
detected, this data may then occur 15 ms before or after
the pin is activated.

7.7 Audio functions

7.7.1 D

E-EMPHASIS AND PHASE LINEARITY

When pre-emphasis is detected in the Q-channel
subcode, the digital filter automatically includes a
de-emphasis filter section. When de-emphasis is not
required, a phase compensation filter section controls the
phase of the digital oversampling filter to ≤±1° within the
band 0 to 16 kHz. With de-emphasis the filter is not phase
linear.

If the de-emphasis signal is set to be available at V5,
selected via register D, then the de-emphasis filter is
bypassed.

7.7.2 D

IGITAL OVERSAMPLING FILTER

The SAA7376 contains a 2 to 4 times oversampling IIR
filter. The filter specification of the 4 times oversampling
filter is given in Table 3.

These attenuations do not include the sample-and-hold at
the external DAC output or the DAC post filter. When using
the oversampling filter, the output level is scaled −0.5 dB
down, to avoid overflow on full-scale sine wave inputs
(0 to 20 kHz).

Table 3 Filter specification

PASS BAND STOP BAND ATTENUATION

0 to 9 kHz −≤0.001 dB

19 to 20 kHz −≤0.03 dB

− 24 kHz ≥25 dB

− 24 to 27 kHz ≥38 dB

− 27 to 35 kHz ≥40 dB

− 35 to 64 kHz ≥50 dB

− 64 to 68 kHz ≥31 dB

− 68 kHz ≥35 dB

− 69 to 88 kHz ≥40 dB

1998 Feb 26 14

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

7.7.3 CONCEALMENT
A 1-sample linear interpolator becomes active if a single

sample is flagged as erroneous but cannot be corrected.
The erroneous sample is replaced by a level midway
between the preceding and following samples. Left and
right channels have independent interpolators. If more
than one consecutive non-correctable sample is found, the
last good sample is held. A 1-sample linear interpolation is
then performed before the next good sample (see Fig.10).

7.7.4 M

UTE, FULL SCALE, ATTENUATION AND FADE

A digital level controller is present on the SAA7376 which
performs the functions of soft mute, full scale, attenuation
and fade; these are selected via register 0:

Mute: signal reduced to 0 in a maximum of 128 steps;
3 ms.

Attenuate: signal scaled by −12 dB.
Full scale: ramp signal back to 0 dB level. From mute

takes 3 ms.

Fade: activates a 128 stage counter which allows the
signal to be scaled up/down by 0.07 dB steps

128 = full scale.
120 = −0.5 dB (i.e. full scale if oversampling filter

used).
32 = −12 dB.
0 = mute.

7.7.5 P

EAK DETECTOR

The peak detector measures the highest audio level
(absolute value) on positive peaks for left and right
channels. The 8 most significant bits are output in the
Q-channel data in place of the CRC bits. Bits 81 to 88
contain the left peak value (bit 88 = MSB) and
bits 89 to 96 contain the right peak value (bit 96 = MSB).
The values are reset after reading Q-channel data via
SDA.

Fig.10 Concealment mechanism.

Interpolation Hold Interpolation

MGA372

OK Error OK Error Error Error OK OK

1998 Feb 26 15

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

7.8 DAC interface

The SAA7376 is compatible with a wide range of digital-to-analog converters (DACs). Nine formats are supported and
are given in Table 4. Figures 11 and 12 show the Philips I2S-bus and the EIAJ data formats respectively. All formats are
MSB first and fs is 44.1 kHz. The polarity of the WCLK and the data can be inverted; selectable by register 7.

Table 4 DAC interface formats

Note

1. In this mode the first 16 bits contain data, but if any of the fade, attenuate or de-emphasis filter functions are activated
then the first 18 bits contain data.

REGISTER 3

SAMPLE

FREQUENCY

NUMBER OF

BITS

SCLK (MHz) FORMAT INTERPOLATION

1110 f

s

16/18

(1)

2.1168 Philips I2S-bus; 16/18 bits

(1)

yes

0010 f

s

16 2.1168 EIAJ 16 bits yes

0110 f

s

18 2.1168 EIAJ 18 bits yes

0000 4f

s

16 8.4672 EIAJ 16 bits yes

0100 4f

s

18 8.4672 EIAJ 18 bits yes

1100 4f

s

18 8.4672 Philips I2S-bus; 18 bits yes

0011 2f

s

16 4.2336 EIAJ 16 bits yes

0111 2f

s

18 4.2336 EIAJ 18 bits yes

1111 2f

s

18 4.2336 Philips I2S-bus; 18 bits yes

1998 Feb 26 16

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc

decoder (CD7)

SAA7376

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LEFT CHANNEL DATA (WCLK NORMAL POLARITY)

SCLK

15 14

15 1410DATA

WCLK

01

MGD036

Fig.11 Philips I2S-bus data format (16-bit word length shown).

SCLK

17

170DATA

WCLK

0

LEFT CHANNEL DATA

MGD035

Fig.12 EIAJ data format (18-bit word length shown).

1998 Feb 26 17

Philips Semiconductors Product specifications

Digital servo processor and Compact Disc
decoder (CD7)

SAA7376

7.9 EBU interface

The bi-phase mark digital output signal at pin DOBM is
in accordance with the format defined by the IEC958
specification. The DOBM pin can be held LOW and
selected via register A.

7.9.1 FORMAT
The digital audio output consists of 32-bit words

(‘subframes’) transmitted in bi-phase mark code (two
transitions for a logic 1 and one transition for a logic 0).
Words are transmitted in blocks of 384. Table 5 gives the
formats.

Table 5 Format

Table 6 Description of Table5

Table 7 Bit assignment

FUNCTION BITS DESCRIPTION

Sync 0 to 3 −
Auxiliary 4 to 7 not used; normally zero
Error flags 4 CFLG error and interpolation flags when selected by register A
Audio sample 8 to 27 first 4 bits not used (always zero). 2’s compliment. LSB = bit 12, MSB = bit 27
Validity flag 28 valid = logic 0
User data 29 used for subcode data (Q-to-W)
Channel status 30 control bits and category code
Parity bit 31 even parity for bits 4 to 30

FUNCTION DESCRIPTION

Sync The sync word is formed by violation of the bi-phase rule and therefore does not contain any data.

Its length is equivalent to 4 data bits. The 3 different sync patterns indicate the following situations:
sync B: start of a block (384 words), word contains left sample; sync M: word contains left sample

(no block start) and sync W: word contains right sample.
Audio sample Left and right samples are transmitted alternately.
Validity flag Audio samples are flagged (bit 28 = 1) if an error has been detected but was uncorrectable. This

flag remains the same even if data is taken after concealment.
User data Subcode bits Q-to-W from the subcode section are transmitted via the user data bit. This data is

asynchronous with the block rate.
Channel status The channel status bit is the same for left and right words. Therefore a block of 384 words contains

192 channel status bits. The category code is always CD. The bit assignment is given in Table 7.

FUNCTION BITS DESCRIPTION

Control 0 to 3 copy of CRC checked Q-channel control bits 0 to 3; bit 2 is logic 1 when copy

permitted; bit 3 is logic 1 when recording has pre-emphasis
Reserved mode 4 to 7 always zero
Category code 8 to 15 CD: bit 8 = logic 1, all other bits = logic 0
Clock accuracy 28 to 29 set by register A; 10 = level I; 00 = level II; 01 = level III
Remaining 16 to 27 and

30 to 191

always zero