SONY CXD2500BQ

CXD2500BQ
CD Digital Signal Processor
Description
The CXD2500BQ is a digital signal processing LSI
designed for use in compact disc players. It has the
following functions:
80 pin QFP (Plastic)
• Wide-frame jitter margin (±28 frames) realized by a
built-in 32K RAM.
• Bit clock generated by digital PLL for strobing EFM
signals. Capture range of ±150 kHz and over.
• EFM data demodulation
• Enhanced protection of EFM Frame Sync signals
• Powerful error correction based on Refined Super
Strategy
Error correction C1: Double correction
C2: Quadruple correction
• Double-speed playback and vari-pitch playback
• Reduced noise generation at track jump
• Auto zero-cross muting
• Subcode demodulation and subcode Q data error
detection
• Digital spindle servo system (incorporating an
oversampling filter)
• 16-bit traverse counter
• Built-in asymmetry correction circuit
• CPU interface using a serial bus
• Servo auto sequencer
• Output for digital audio interface
• Built-in digital level meter and peak meter
• Bilingual
Features
• All digital signals for regeneration are processed
using one chip.
• The built-in RAM enables high-integration
mounting.
Structure
Silicon-gate CMOS IC
Sony reserves the right to change products and specifications without prior notice. This information does not convey any license by
any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the
operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits.
—1—
E91Y46F64-TE
CXD2500BQ
Absolute Maximum Ratings (Ta=25 °C)
• Supply voltage
VCC
• Input voltage
VI
• Output voltage
VO
• Operating temperature
Topr
• Storage temperature
Tstg
• Supply voltage differences
VSS–AVSS
VDD–AVDD
Recommended Operating Conditions
• Supply voltage
VDD
• Operating temperature
Topr
• Input voltage
VIN
–0.3 to +7.0
–0.3 to +7.0
–0.3 to +7.0
–20 to +75
–40 to +125
–0.3 to +0.3
–0.3 to +0.3
V
V
V
°C
°C
V
V
4.75∗1 to 5.25∗3 (5.0 V typ.)
–20 to +75
VSS–0.3 to + VDD + 0.3
V
°C
V
∗1 VDD value of 4.75 V (min.) is for the double-speed playback mode at vari-pitch control reset. For the low
power consumption special playback mode, VDD value is 3.6 V (min.). ∗2 In the normal-speed playback
mode VDD value is 4.5 V (min.)
∗2 Low power consumption, special playback mode
Set the internal operation of LSI at the double-speed mode, and half the crystal oscillation frequency. This
will result in the normal-speed playback mode.
∗3 VDD value of 5.25 V (max.) is for the double-speed playback mode at vari-pitch control reset. For normalspeed playback and the low power consumption special playback mode, the VDD value is 5.5 V (max.).
I/O Capacity
• Input pins
CI 12 pF max.
• Output pins
CO 12 pF max. at high impedance
Note: Test Conditions
VDD=VI=0 V
fM=1 MHz
—2—
CXD2500BQ
VCKI
VPCO
53
XTAO
XTAI
56
XTSL
FSTT
Block Diagram
54
53
17
19
C4M 57
23 AVDD
Clock
generator
C16M 58
21 AVSS
32K RAM
PDO 11
Digital PLL
vari-pitch
double speed
8
EFM
demodulator
12 VSS
Address
generator
PCO 20
FIL1 19
Priority
encoder
8
FIL0 18
Sync
Protector
CLTV 22
D/A
data processor
RF 24
ASY1 26
52 VSS
Serial/Parallel
processor
VCO0
73 VDD
9
Register
VCO1
33 VDD
∗
30 PSSL
49 DAO 1 to 6
MUX
68 MUTE
ASY0 27
ASYE 28
Timing
Generator
WFCK 62
Peak detector
SCOR 63
EXCK 65
Digital out
Subcode
P-W
Processor
SBSO 64
60 DOUT
59 MD 2
EMPH 61
71 DATA
SQCK 67
SQSO 66
MON
Error corrector
Subcode
Q
Processor
74 CLOK
CPU interface
72 XLAT
3
FSW
2
MDP
4
CLV
processor
MDS 43
Noise
shaper
TEST 10
77 DATO
Servo
auto
sequencer
Timing
Generator 2
79 CLKO
78 XLTO
18-times
over samplling
filter
NC
∗Asymmetry
correction.
32
31
75 69
76
80
1
WDCK
SEIN
MIRR
CNIN
FOX
—3—
SENS
51
LRCK
LOCK
50
APTL
6
APTR
70
XRST
5
CXD2500BQ
DA08
DA09
45 44
43 42
41
DA07
46
DA06
DA04
48 47
DA05
DA03
50 49
DA02
52 51
DA01
VSS
53
APTR
XTAI
55 54
APLL
XTAQ
57 56
XTSL
59 58
FSTT
MD2
60
C4M
DOUT
62 61
C16M
EMPH
64 63
WFCK
SCOR
SBSO
Pin Configuration
EXCK
65
40
DA10
SQSO
66
39
DA11
SQCK
67
38
DA12
MUTE
68
37
DA13
SENS
69
36
DA14
XRST
70
35
DA15
DATA
71
34
DA16
XLAT
72
33
VDD
D2500B
77
28
ASYE
XLTO
78
27
ASYO
CLKO
79
26
ASYI
MIRR
80
25
BIAS
10 11
12
13 14
15 16
—4—
17 18
19
20 21
22 23
24
CLTV
9
AVSS
8
PCO
7
FILI
6
FILO
5
VCKI
4
VPCO
3
NC
2
PDO
1
RF
DATO
AVDD
NC
NC
29
NC
76
VSS
CNIN
TEST
PSSL
VCOI
30
VCOO
75
NC
SEIN
LOCK
WDCK
MDS
CLOK
31
MDP
LRCK
74
MON
32
FSW
73
FOK
VDD
CXD2500BQ
Pin Description
Pin
No.
1
2
3
4
5
Symbol
I/O
Description
FOK
FSW
MON
MDP
MDS
I
O
O
O
O
Z, 0
1, 0
1, Z, 0
1, Z, 0
6
LOCK
O
1, 0
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
NC
VCOO
VCOI
TEST
PDO
VSS
NC
NC
NC
VPCO
VCKI
FILO
FILI
PCO
AVSS
CLTV
AVDD
RF
BIAS
ASYI
ASYO
ASYE
NC
30
PSSL
I
31
32
33
WDCK
LRCK
VDD
O
O
34
DA16
O
35
DA15
O
36
DA14
O
37
38
39
40
DA13
DA12
DA11
DA10
O
O
O
O
Focus OK input. Used for SENS output and servo auto sequencer.
Output used to switch the spindle motor output filter.
Output for spindle motor ON/OFF control
Output for spindle motor servo control
Output for spindle motor servo control
Output is “H” when the GFS signal sampled at 460 Hz is “H”. Output is
“L” when the GFS signal is “L” 8 or more times in succession.
—
O
I
I
O
1, 0
1, Z, 0
Output of oscillation circuit for analog EFM PLL
Input to oscillation circuit for analog EFM PLL fLOCK=8.6436 MHz
Test. Normally at 0 V (GND).
Output of charge pump for analog EFM PLL
GND
—
—
—
O
I
O
I
O
I
I
I
I
O
I
1, Z, 0
Output of charge pump for vari-pitch PLL
Clock input from external VCO for vari-pitch control. fc center=16.9344 MHz.
Analog Output of filter for master PLL (Slave=Digital PLL)
Input to filter for master PLL
1, Z, 0 Output of charge pump for master PLL
Analog GND
VCO control voltage input for master PLL
Analog power supply (+5 V)
EFM signal input
Asymmetry circuit constant current input
Asymmetry comparator circuit voltage input
1, 0
EFM full-swing output
Asymmetry circuit OFF at “L”. Asymmetry circuit ON at “H”.
—
Input used to switch the audio data output mode. “L” for serial output,
“H” for parallel output.
1, 0
D/A interface for 48-bit slot. Word clock f=2Fs
1, 0
D/A interface for 48-bit slot. LR clock f=Fs
Power supply (+5 V)
Outputs DA16 (MSB) when PSSL=1, or serial data from the 48-bit slot
1, 0
(2’s complements, MSB first) when PSSL=0.
1, 0
Outputs DA15 when PSSL=1, or bit clock from the 48-bit slot when PSSL=0.
Outputs DA14 when PSSL=1, or serial data from the 64-bit slot (2’s
1, 0
complements, LSB first) when PSSL=0.
1, 0
Outputs DA13 when PSSL=1, or bit clock from the 64-bit slot when PSSL=0.
1, 0
Outputs DA12 when PSSL=1, or LR clock from the 64-bit slot when PSSL=0.
1, 0
Outputs DA11 when PSSL=1, or GTOP when PSSL=0.
1, 0
Outputs DA10 when PSSL=1, or XUGF when PSSL=0.
—5—
CXD2500BQ
Pin
No.
Symbol
I/O
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
DA09
DA08
DA07
DA06
DA05
DA04
DA03
DA02
DA01
APTR
APTL
VSS
XTAI
XTAO
XTSL
O
O
O
O
O
O
O
O
O
O
O
56
FSTT
O
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
C4M
C16M
MD2
DOUT
EMPH
WFCK
SCOR
SBSO
EXCK
SQSO
SQCK
MUTE
SENS
XRST
DATA
XLAT
VDD
CLOCK
SEIN
CNIN
DATO
XLTO
CLKO
O
O
I
O
O
O
O
O
I
O
I
I
—
I
I
I
80
MIRR
I
I
O
I
I
I
I
O
O
O
Description
1, 0
1, 0
1, 0
1, 0
1, 0
1, 0
1, 0
1, 0
1, 0
1, 0
1, 0
Outputs DA9 when PSSL=1, or XPLCK when PSSL=0.
Outputs DA8 when PSSL=1, or GFS when PSSL=0.
Outputs DA7 when PSSL=1, or RFCK when PSSL=0.
Outputs DA6 when PSSL=1, or C2PO when PSSL=0.
Outputs DA5 when PSSL=1, or XRAOF when PSSL=0.
Outputs DA4 when PSSL=1, or MNT3 when PSSL=0.
Outputs DA3 when PSSL=1, or MNT2 when PSSL=0.
Outputs DA2 when PSSL=1, or MNT1 when PSSL=0.
Outputs DA1 when PSSL=1, or MNT0 when PSSL=0.
Control output for aperture correction. “H” for R-ch.
Control output for aperture correction. “H” for L-ch.
GND
Input for 16.9344 MHz and 33.8688 MHz X'tal oscillation circuit.
1, 0
Output for 16.9344 MHz X'tal oscillation circuit.
X'tal selection input. “L” for 16.9344 MHz X'tal, “H” for 33.8688 MHz X'tal.
2/3 frequency demultiplication output for Pins 53 and 54. Unaffected by
1, 0
vari-pitch control.
1, 0
4.2336 MHz output. Subject to vari-pitch control.
1, 0
16.9344 MHz output. Subject to vari-pitch control.
Digital-Out ON/OFF control. “H” for ON, “L” for OFF.
1, 0
Digital-Out output.
1, 0
“H” for playback disc provided with emphasis, “L” for without emphasis.
1, 0
WFCK (Write Frame Clock) output.
1, 0
“H” when subcode Sync S0 or S1 is detected.
1, 0
Serial output of Sub P to W
Clock input for reading SBSO
1, 0
Outputs 80-bit Sub Q and 16-bit PCM peak-level data.
Clock input for reading SQSO
“H” for muting, “L” for release.
1, Z, 0 SENS output to CPU
System reset. “L” for resetting.
Inputs serial data from CPU.
Latches serial data input from CPU at falling edge.
Power supply (+5 V)
Inputs serial data transfer clock from CPU.
Inputs SENSE from SSP.
Inputs track jump count signal.
1, 0
Outputs serial data to SSP.
1, 0
Latches serial data output to SSP at falling edge.
1, 0
Outputs serial data transfer clock to SSP.
Inputs mirror signal to be used by auto sequencer when jumping 16 or
more tracks.
—6—
CXD2500BQ
Note:
• The data at the 64-bit slot is output in 2’s complements on an LSB-first basis. The data at the 48-bit slot is
output in 2’s complements on an MSB-first basis.
• GTOP monitors the state of Frame Sync protection. (“H”: Sync protection window released)
• XUFG is a negative Frame Sync pulse obtained from the EFM signal before Frame Sync protection is
effected..
• XPLCK is an inversion of the EFM PLL clock. The PLL is designed so that the falling edge of XPLCK
coincides with a change point of the EFM signal.
• The GFS signal turns “H” upon coincidence between Frame Sync and the timing of interpolation protection.
• RFCK is a signal generated at 136-µs periods using a crystal oscillator.
• C2PO is a signal to indicate data error.
• XRAOF is a signal issued when a jitter margin of ±28F is exceeded by the 32K RAM.
—7—
CXD2500BQ
Item
Input voltage.
“H” level
Input voltage
“L” level.
Input voltage
“H” level
Input voltage
“L” level
Input voltage
Output
voltage (3)
Output voltage
“H” level
Output voltage
“L” level
Output voltage
“H” level
Output voltage
“L” level
Output voltage
“L” level
Output
voltage (4)
Output
voltage (2)
Output
voltage (1)
Input
voltage (3)
Input
voltage (2)
Input
voltage (1)
Electrical Character
DC characteristics
Output voltage
“H” level
Output voltage
“L” level
(VDD=AVDD=5.0 V±5 %, VSS=AVSS=0 V, Topr=–20 to +75°C)
Condition
Min.
Typ.
Max.
0.7VDD
VIH (1)
Unit
Related pins
V
∗1
VIL (1)
VIN (2)
VIN (2)
VIN (3)
0.3VDD
Schmitt circuit
input
0.8VDD
V
∗2
0.2VDD
V
VSS
VDD
V
VDD–0.5
VDD
V
Analog input
VOH (1) IOH=–1 mA
V
∗3
∗4
VOL (1)
IOL=1 mA
VOH (2) IOH=–1 mA
0
0.4
V
VDD–0.5
VDD
V
∗5
VOL (2)
IOL=2 mA
0
0.4
V
VOL (3)
IOL=2 mA
0
0.4
V
VDD–0.5
VDD
V
VOH (4) IOH=–0.28 mA
∗6
∗7
VOL (4)
IOL=0.36 mA
0
0.4
V
Input leak current
ILI
VI=0 to 5.25 V
±5
µA
∗1, ∗2, ∗3
Tristate pin output leak
current
ILO
VO=0 to 5.25 V
±5
µA
∗8
Related pins
∗1 XTSL, DATA, XLAT, MD2, PSSL
∗2 CLOK, XRST, EXCK, SQCK, MUTE, FOK, SEIN, CNIN, MIRR, VCKI, ASYE
∗3 CLTV, FILI, RF
∗4 MDP, PDO, PCO, VPCO
∗5 ASYO, DOUT, FSTT, C4M, C16M, SBSO, SQSO, SCOR, EMPH, MON, LOCK, WDCK, DATO, CLKO,
XLTO, SENS, MDS, DA01 to DA16, APTR, APTL, LRCK, WFCK
∗6 FSW
∗7 FILO
∗8 SENS, MDS, MDP, FSW, PDO, PCO, VPCO
—8—
CXD2500BQ
AC Characteristics
(1) XTAI and VCOI pins
1) During self-oscillation
(Topr=–20 to +75 °C, VDD=AVDD=5.0 V±5 %)
Item
Oscillation frequency
Symbol
fMAX
2) With pulses input to XTAI and VCOI pins
Item
Symbol
Min.
7
Typ.
Max.
34
Unit
MHz
(Topr=–20 to +75 °C, VDD=AVDD=5.0 V±5 %)
Typ.
Max.
Unit
Min.
“H” level pulse width
tWHX
13
500
“L” level pulse width
tWLX
13
500
Pulse period
tCX
26
1,000
Input “H” level
VIHX
VDD–1.0
ns
V
Input “L” level
VILX
0.8
Rising time
Falling time
tR, tF
10
ns
tCX
tWHX
tWLX
VIHX
VIHX×0.9
VDD/2
XTAI
VIHX×0.1
VILX
tR
tF
3) With sine waves input to XTAI and VCOI pins via capacitor
(Topr=–20 to +75 °C, VDD=AVDD=5.0 V±5 %)
Item
Input amplitude
Symbol
V1
—9—
Min.
2.0
Typ.
Max.
VDD+0.3
Unit
Vp-p
CXD2500BQ
(1) CLOK, DATA, XLAT, CNIN, SQCK, and EXCK pins
(VDD=AVDD=5.0 V±5 %, VSS=AVSS=0 V, Topr=–20 to +75 °C
Item
Clock frequency
Clock pulse width
Setup time
Hold time
Delay time
Latch pulse width
EXCK, CNIN, SQCK frequency
EXCK, CNIN, SQCK pulse width
Symbol
fCK
tWCK
tSU
tH
tD
tWL
fT
tWT
Min.
Typ.
Max.
0.65
750
300
300
300
750
Unit
MHz
ns
1
MHz
ns
300
1/fCK
tWCK
tWCK
CLOK
DATA
XLAT
tSU
tH
tD
EXCK
CNIN
SQCK
tWT
tWL
tWT
1/fT
SUBQ
SQCK
tSU
tH
Description of Functions
§1
CPU Interface and Commands
• CPU interface
This interface is used to set various modes using DATA, CLOK, and XLAT.
The interface timing chart is shown below.
750ns or more
CLOK
DATA
D1
D2
Data
D3
D0
D1
D2
D3
Address
750ns or more
XLAT
Registers 4 to E
Valid
300ns max
• The command addresses of the CXD2500B and the data capable of being set are shown in Table 1-1.
• When XRST is set to 0, the CXD2500B is reset, causing its internal registers to be initialized to the values
listed in Table 1-2.
—10—
—11—
Servo factor setting
CLV CRTL
CLV mode
D
E
counter setting
Traverse monitor
C
B
Audio CTRL
Func specification
9
A
MODE specification
jump (N) setting
Auto sequencer track
KICK (D)
Brake (B)
Blind (A, E), Overflow (C)
8
7
6
5
1
1
1
1
1
1
1
0
0
0
0
4
Auto sequence
D3
Command
name
Register
Commands
1
1
1
0
0
0
0
1
1
1
1
1
0
0
1
1
0
0
1
1
0
0
D1
Address
D2
0
1
0
1
0
1
0
1
0
1
0
D0
D1
AS0
D0
DSPB
D CLV
A SEQ
Mute-F
D OUT
8,192
2.9 ms
D PLL
WSEL
4,096
1.45 ms
0.09 ms 0.045 ms
CM3
PWM MD
DCLV
MDP1
Gain
32,768
UP
Vari
CM2
TB
MDP0
Gain
16,384
Down
Vari
CM1
TP
MDS1
Gain
8,192
Mute
Table 1-1
CM0
Gain
CLVS
MDS0
Gain
4,096
ATT
ON-OFF ON-OFF ON-OFF ON-OFF
0
16,384
5.8 ms
0.18 ms
0.09 ms 0.045 ms 0.022 ms
AS1
Data 1
AS2
D2
CDROM
32,768
11.6 ms
0.36 ms
0.18 ms
AS3
D3
—
—
—
2,048
PCT1
MAIN
BiliGL
—
2,048
—
—
—
D3
—
—
—
1,024
PCT2
SUB
BiliGL
—
—
—
—
D1
—
—
—
512
—
FLFC
—
512
Data 2
1,024
—
—
—
D2
—
—
—
256
—
—
—
256
—
—
—
D0
—
—
—
128
—
—
—
128
—
—
—
D3
—
—
—
64
—
—
—
64
—
—
—
—
—
—
32
—
—
—
32
—
—
—
D1
Data 3
D2
—
—
—
16
—
—
—
16
—
—
—
D0
—
—
—
8
—
—
—
8
—
—
—
D3
—
—
—
4
—
—
—
4
—
—
—
—
—
—
2
—
—
—
2
—
—
—
D1
Data 4
D2
—
—
—
1
—
—
—
1
—
—
—
D0
CXD2500BQ
—12—
Servo factor setting
CLV CRTL
CLV mode
D
E
counter setting
Traverse monitor
C
B
Audio CTRL
Func specification
9
A
MODE specification
track jump setting
Auto sequencer
KICK (D)
Brake (B)
Blind (A, E), Overflow (C)
Auto sequence
Command
8
7
6
5
4
name
Register
Reset Initialization
1
1
1
1
1
1
1
0
0
0
0
D3
1
1
1
0
0
0
0
1
1
1
1
D2
1
0
0
1
1
0
0
1
1
0
0
D1
Address
0
1
0
1
0
1
0
1
0
1
0
D0
0
0
0
0
0
1
0
0
0
0
0
D3
0
0
1
0
0
0
0
0
1
1
0
D2
Data 1
0
0
1
0
1
0
0
0
1
0
0
D1
Table 1-2
0
0
0
0
1
1
0
0
1
1
0
D0
—
—
—
0
0
0
—
0
—
—
—
D3
—
—
—
0
0
0
—
0
—
—
—
D2
Data 2
—
—
—
0
—
0
—
0
—
—
—
D1
—
—
—
1
—
—
—
1
—
—
—
D0
—
—
—
0
—
—
—
0
—
—
—
D3
—
—
—
0
—
—
—
0
—
—
—
D2
—
—
—
0
—
—
—
0
—
—
—
D1
Data 3
—
—
—
0
—
—
—
0
—
—
—
D0
—
—
—
0
—
—
—
0
—
—
—
D3
—
—
—
0
—
—
—
0
—
—
—
D2
—
—
—
0
—
—
—
0
—
—
—
D1
Data 3
—
—
—
0
—
—
—
0
—
—
—
D0
CXD2500BQ
CXD2500BQ
§1
Meanings of Data Set at Command Addresses
$4X Command
Command
CANCEL
FOCUS-ON
1 TRACK JUMP
10 TRACK JUMP
2N TRACK JUMP
M TRACK MOVE
AS3
0
0
1
1
1
1
AS2
0
1
0
0
1
1
AS1
0
1
0
1
0
1
AS0
0
1
RXF
RXF
RXF
RXF
RXF=0 FORWARD
RXF=1 REVERSE
• If a Focus-ON command ($47) is canceled during execution, $02 is issued and the auto sequence operation
is discontinued.
• If a Track Jump or Track Move command ($48 to $4F) is canceled during execution, the auto sequence
operation is discontinued.
$5X Command
Used to set timers for the auto sequencer.
Timers set: A, E, C, and B
Command
Blind(A, E), Overflow(C)
Brake(B)
Example:
D3
0.18 ms
0.36 ms
D1
0.045 ms
0.09 ms
D0
0.022 ms
0.045 ms
D2
5.8 ms
D1
2.9 ms
D0
1.45 ms
Data 3
D3 D2 D1 D0
Data 4
D3 D2 D1 D0
27
23
D2=D0=1, D3=D1=0 (Initial Reset)
A=E=C=0.112 ms
B=0.225 ms
$6X Command
Used to set a timer for the auto sequencer.
Timer set: D
Command
D3
KICK (D)
11.6 ms
Example:
D2
0.09 ms
0.18 ms
D3=0 D2=D1=D0=1 (Initial Reset)
D=10.15ms
$7X Command
Used to set the number of auto sequencer track jumps/moves.
Data3
Data 2
Command
D3 D2 D1 D0 D3 D2 D1 D0
Auto sequencer track
jump number setting
215
214
213
212
211
210
29
28
26
25
24
22
21
20
This command sets the value of “N” for 2N track jump and M track move execution using the auto sequencer.
—13—
CXD2500BQ
• The maximum number of tracks that can be counted is 65,535. However, in the case of 2N track jumps, it is
subject to mechanical restrictions due to the optical system.
• When the number of tracks to be jumped is smaller that 15, the signals input from CNIN are counted. When
it is 16 or larger, the signals input from the MIRR pin are counted. This count signal selection contributes
toward improving the accuracy of high-speed track jumping.
Command
D3
D2
MODE specification
CDROM
0
$8X Command
Command
C2PO timing
CDROM=1
1-3
CDROM=0
1-3
Command bit
D. out Mute F=1
D. out Mute F=0
D1
D. OUT
Mute-F
AS0
WSEL
Processing
CDROM mode is entered. In this mode, average value
interpolation and preceding value holding are not performed.
Audio mode is entered. In this mode, average value
interpolation and preceding value holding are performed.
Processing
When Digital Out is ON (pin MD2=1), DA output is muted.
Da output muting is unaffected by the setting of Digital Out.
D/A Out D.out Mute with F=1
MD2=1
(D. out-ON)
– ∞dB
– ∞dB
Mute-ON
Mute-OFF
Command bit
WSEL=1
WSEL=0
MD2=0
(D. out-OFF)
– ∞dB
0dB
Sync protection window width
Application
∗
±26 channel clock pulses
Anti-rolling is enhanced.
±6 channel clock pulses
Sync window protection is enhanced.
∗ In normal-speed playback, the channel clock frequency is 4.3218 MHz.
$9X Command
Command
Func specification
Data 1
D3
DCLV
ON-OFF
D2
DSPB
ON-OFF
D1
A. SEQ
ON-OFF
—14—
D0
D. PLL
ON-OFF
D3
BiliGL
MAIN
Data 2
D2
BiliGL
Sub
D1
FLFC
CXD2500BQ
Command bit
CLV mode
DCLV ON-OFF=0
DCLV ON-OFF=1
(FSW and MON are
unnecessary)
Contents
FSW=L, MON-H, MDS-Z, MDP=servo control signal, with carrier
In CLVS mode
frequency of 230 Hz at TB=0 and 460 Hz at TB=1
FSW=Z, MON=H, MDS=speed control signal with carrier frequency of
In CLVP mode
7.35 kHz, MDP=phase control signal with carrier frequency of 1.84 kHz
MDS= PWM polarity signal. Carrier
DCLV when
frequency=132 kHz
PWM, MD=1
MDS= PWM absolute value output (binary).
In CLVS or
Carrier frequency=132 kHz
CLVP mode
MDS= Z
DCLV when
MDP= ternay PWM output.
PWM, MD=0
Carrier frequency=132 kHz
In the Digital CLV servo mode with DCLV ON-OFF set to 1, the sampling frequency of the internal digital filter
is switched at the same time as the switching between CLVP and CLVS.
Therefore, for CLVS, the cut-off frequency fC is 70 Hz when TB is set to 0, and 140Hz when TB is set to 1.
Command bit
DSPB=0
DSPB=1
Processing
Normal-speed playback. ECC quadruple error correction is made. Vari-pitch
control is enabled.
Double-speed playback. ECC double error correction is made. Vari-pitch control
is disabled.
Set FLFC at 1 when in double-speed playback mode (exclude the low power consumption special playback
mode). However, FLFC can be set to 0 during PLL pull-in (lock). Set to 0 for all other modes.
SENS Output
Microcomputer serial register
values (Latching unnecessary)
$0X
$1X
$2X
$3X
$4X
$5X
$6X
$AX
$BX
$CX
$EX
$7X, 8X, 9X, DX, FX
ASEQ=0
ASEQ=1
Z
Z
Z
Z
Z
Z
Z
GFS
COMP
COUT
OV64
Z
SEIN (FZC)
SEIN (A, S)
SEIN (T. Z. C)
SEIN (SSTOP)
XBUSY
FOK
SEIN (Z)
GFS
COMP
COUT
OV64
0
—15—
CXD2500BQ
Description of SENS signals
SENS output
Z
SEIN
XBUSY
FOK
GFS
COMP
COUT
OV64
Command bit
DPLL=0
DPLL=1
Command bit
BiliGL SUB=0
BiliGL SUB=1
Meaning
SENS is at High-Z state.
SEIN signal, which was input to the CXD2500B, is output from SSP.
“L” when auto sequencer is in operation; “H” when terminated.
Output of the signal (normally FOK input from RF) input to the FOK pin. “H” when
Focus OK is received.
“H” when regenerated Frame Sync is obtained at the correct time.
Used in counting the number of tracks set in register B. “H” when the count is
latched to register B twice in succession. It is reset to “L” level when the count of
CNIN inputs equals the originally set number for register B.
Used in counting the number of tracks set in register B. “H” when the count is
latched to register B, then to register C. It is toggled every time the count of CNIN
inputs reaches the value set in register B.
“L” when after passing through the sync detection filter, the EFM signal become
longer than the 64 channel clocks.
Meaning
RFPLL enters analog mode. PDO, VCOI, and VCOO are used.
RFPLL enters digital mode. PDO becomes Z.
BiliGL
MAIN=0
STEREO
SUB
BiliGL
MAIN=1
MAIN
Mute
Definition of Bilingual MAIN, SUB, and STEREO
MAIN; The input L-ch signal is output to both L-ch and R-ch.
Sub: The input R-ch signal is output to both L-ch and R-ch.
STEREO: The input L-ch and R-ch signals are output to both L-ch and R-ch respectively.
—16—
CXD2500BQ
$AX Command
Command
Audio CTRL
Data 1
D3
Vari
UP
D2
Vari
DWN
Data 2
D1
D0
D3
D2
Mute
ATT
PCT1
PCT2
Vari UP
Vari DWN
Pitch
XTal 0% VCO 0% +0.1% +0.2% +0.3%
+0.2% +0.1%
+0%
Command bit
Meaning
Mute=0
Muting is off unless condition to make muting occurs.
Mute=1
Muting is on. Peak register reset.
-0.1% -0.2%
XTal 0%
Command bit
Meaning
ATT=0
Attenuation is off.
ATT=1
–12dB
Condition for Muting
(1) Mute=1 in register A
(2) Pin Mute=1
(3) D.OUT Mute F=1 in register 8 with D.Out ON (MD2=1)
(4) Elapse of over 35 msec after GFS turns “Low”
(5) BiliGL MAIN=Sub=1 in register 9
(6) PCT1=1 and PCT2=2 in register A
In the case of (1) to (4), zero-cross muting not exceeding 1 msec is performed.
Command bit
Meaning
PCM Gain
PCT1
PCT2
0
0
Normal mode
×0 dB
0
1
Level meter mode
×0 dB
1
0
Peak meter mode
Mute
1
1
Normal mode
×0 dB
ECC correction capacity
C1: Double, C2: Quadruple
C1: Double, C2: Quadruple
C1: Double, C2: Double
C1: Double, C2: Double
Level Meter Mode (See Timing Chart 1-4.)
• This mode makes the digital level meter function available.
• Inputting 96-bit clock pulses to SQCK will enable 96 data to be output to SQSO. Of the output data, the first
80 bits comprise Sub-Q data, which transmit the description for the data format to the Sub Code interface.
The last 16 bits are ordered LSB-first, of which the first 15 bits constitute PCM data (absolute value). The
final 1 bit is “High” if the prior PCM data was generated at the left channel; “Low” if generated at the right
channel.
• The PCM data is reset once it is read, and the L/R flag is reversed. While this state is kept until the next
read operation is started, testing for the maximum value is conducted.
—17—
CXD2500BQ
Peak Meter Mode (See Timing Chart 1-5.)
• In this mode, the maximum value of PCM data is detected whether the channel involved is L-ch or R-ch.
To read the detected maximum value, it is necessary to input 96 clock pulses to SQCK.
• When 96 clock pulses have been input to SQCK, 96 bits of data is output to SQSO. At the same time, the
data is re-set in an internal register of the LSI.
That is, the PCM peak detection register is not reset when it is read.
• To reset the PCM peak register, set both PCT1 and PCT2 to 0. Or, Set $AX mute.
• In this mode, the absolute time of Subcode Q is controlled automatical.
• Namely, every time a peak value is detected, the absolute time when the CRC was passed is stored. The
program time operation is performed in the normal way.
• The last bit (L/R flag) of the 96-bit data stays 0.
• In this mode, the preceding value holding and average value interpolation data are fixed to level (–∞).
$CS Command
Command
Servo factor setting
D3
Gain
MDP1
D2
Gain
MDP0
D1
Gain
MDS1
CLV CTRL ($DX)
D0
Gain
MDS0
Gain
CLVS
Explanation
Only DCLV=1 is effective.
DCLV=1 and DCLV=0 are both
effective.
This command is used to externally set the spindle servo gain when DCLV=1.
• Gain setting for CLVS mode: GCLVS
Gain
Gain
Gain
MDS1
MDS0
CLVS
0
0
0
0
0
1
0
1
0
0
1
1
1
0
0
1
0
1
GCLVS
Note:
–12dB
–6dB
–6dB
0dB
0dB
+6dB
When DCLV=0, the CLVS gain is
determined as follows:
If Gain CLVS=0, then GCLVS=–12 dB.
If Gain CLVS=1, then GCLVS=0 dB
• Gain setting for CLVP mode: GMDP, GMDS
Gain
MDP1
0
0
1
Gain
MDP0
0
1
0
GMDP
–6 dB
0 dB
+ 6dB
Gain
MDS1
0
0
1
—18—
Gain
MDS0
0
1
0
GMDS
–6dB
0dB
+6dB
CXD2500BQ
$DC Command
Command
D3
D2
CLV CTRL
DCLV
PWM MD
TB
D1
TP
D0
CLVS
Gain
See “$CX Command.”
Command bit
DCLV PWM MD=1
DCLV PWM MD=0
Command bit
TB=0
TB=1
TP=0
TP=1
Description (See Timing Chart 1-6.)
Specification of PWM mode for digital CLV. Both MDS and MDP are used.
Specification of PWM mode for digital CLV. Ternary MDP values are output.
Description
In CLVS or CLVH mode, bottom value is held at periods of RFCK/32.
In CLVS or CLVH mode, bottom value is held at periods of RFCK/16.
In CLVS mode, peak value is held at periods of RFCK/4.
In CLVS mode, peak value is held at periods of RFCK/2.
In CLVH mode, peak holding is made at 34 kHz.
$EX Command
Command
CLV mode
CM3
0
1
1
1
1
1
0
STOP:
KICK:
BRAKE:
CLVS:
CLVP:
CLVA:
CM2
0
0
0
1
1
1
1
D3
CM3
D2
CM2
D1
CM1
CM1
0
0
1
1
0
1
1
CM0
0
0
0
0
0
1
0
Mode
STOP
KICK
BRAKE
CLVS
CLVH
CLVP
CLVA
D0
CM0
Explanation
See Timing Chart 1-7.
See Timing Chart 1-8.
See Timing Chart 1-9.
Spindle motor stop mode
Spindle motor forward run mode
Spindle motor reverse run mode
Rough servo mode for use for pulling disc run into RF-PLL capture range when the RF-PLL circuit
lock has been disengaged
PLL servo mode
Automatic switching mode for CLVS and CLVS. This mode is used during normal play status.
—19—
—20—
C2PO
CDROM=1
C2PO
CDROM=0
WDCK
LRCK
Timing Chart 1-3
C2 Pointer for Lower 8bit
Rch C2 pointer
C2 Pointer for upper 8bit
Rch 16bit C2 Pointer
C2 Pointer for Lower 8bit
Lch C2 pointer
C2 Pointer for upper 8bit
Lch 16bit C2 Pointer
If C2 pointer=1,
data is NG
48bit Slot
CXD2500BQ
—21—
SQSO
SQCK
WFCK
SQSO
SQCK
CRCF
Timing Chart 1-4
1
1
2
3
80
81
CRCF
D0
D2
1
16 bit
96 clock pulses
D1
Level Meter Timing
Peak data of this section
Sub-Q Data
See "Sub Code interface"
L/R
3
96 bit data
Hold section
96 clock pulses
2
D4
D5
D6
2
R/L
3
CRCF
15-bit peak-data
Absolute value display, LSB first
D3
750ns to 120µs
D13
D14
96
Peak data
L/R flag
L/R
CXD2500BQ
SQCK
WFCK
96 clock pulses
Measurement
CRCF
Timing Chart 1-5
1
2
3
Peak Meter Timing
Measurement
CRCF
96 clock pulses
1
2
3
Measurement
CRCF
CXD2500BQ
—22—
CXD2500BQ
Timing Chart 1-6
DCLV PWM MD=0
MDS
Z
n·236 (nsec) n=0 to 31
Acceleration
MDP
Z
132KHz
7.6µSec
Deceleration
DCLV PWM MD=1
MDS
Deceleration
Acceleration
MDP
n·236 (nsec) n=0~31
7.6µSec
Output Waveforms with DCLV=1
Timing Chart 1-7
STOP
DCLV=0
MDS
Z
MDP
L
FSW
L
MON
L
DCLV=1 DCLV PWM MD=0
STOP
MDS
Z
MDP
Z
DCLV=1 DCLV PWM MD=1
STOP
MDS
MDP
L
FSW and MON are the same as for DCLV=0
—23—
CXD2500BQ
Timing Chart 1-8
KICK
DCLV=0
MDS
Z
MDP
H
FSW
L
MON
H
DCLV=1 DCLV PWM MD=0
KICK
Z
MDS
MDP
H
Z
7.6µs
FSW and MON are the same as for DCLV=0
DCLV=1 DCLV PWM MD=1
KICK
MDS
MDP
H
H
L
FSW and MON are the same as for DCLV=0
—24—
CXD2500BQ
Timing Chart 1-9
BRAKE
DCLV=0
MDS
Z
MDP
L
FSW
L
MON
H
DCLV=1 DCLV PWM MD=0
BRAKE
MDS
MDP
Z
L
Z
FSW and MON are the same as for DCLV=0
DCLV=1 DCLV PWM MD=1
MDS
MDP
FSW and MON are the same as for DCLV=0
—25—
CXD2500BQ
§2
Subcode Interface
In this section, the subcode interface will be explained.
The contents of the subcode interface can be externally read in two ways. The subcodes P through W totaling
8 bits can be read from SBSO by inputting EXCK to the CXD2500B.
Sub-Q can be read after conducting a CRC check on the 80bits of information in the subcode frame. First,
check SCOR and CRCF, then input 80 clock pulses to SQCK and read the data.
§2-1 P-W Subcode Read
These subcodes can be read by entering EXCK immediately after the fall of WFCK. (See Timing Chart 2-1.)
§2-2 80-bit Sub-Q Read
Figure 2-2 shows a block diagram of the peripheral part of the 80-bit Sub-Q register.
• The Sub Q regenerated on a bit-per-frame basis is input to the 80-bit serial/parallel register and the CRC
circuit.
• When the results of CRC of the 96-bit Sub-Q are OK, CRCF is set to 1 and the 96-bit data is output to
SQSO.
Furthermore, it is loaded into the 80-bit, parallel/serial register.
If SQSO is “H” after the output of SCOR, it can be taken that CPU has been loaded a new set of CRCOK
data.
• When 80-bit data is loaded into CXD2500B, MSB and LSB are reversed within each byte of the data.
Therefore, the bits are ordered LSB-first within each byte, even though the byte arrangement is kept
unchanged.
• When 80 bits of data are confirmed to have been loaded, SQCK is input to read the data. Subsequently in
the CXD2500B, the input of SQCK is detected and the retriggerable monostable multivibrator is reset during
Low.
• The time constant of the retriggerable monostable multivibrator ranges from 270 to 400 µs. If the time of
High for SQCK is less than this time constant, the monostable multivibrator will keep resetting, preventing the
contents of the P/S register from being loaded into the P/S register.
• While the monostable multivibrator is resetting, data loading into the peak detection parallel/serial register
and 80-bit parallel/serial register is forbidden.
Therefore, while data read operation is carried out at clock periods shorter than the time constant of the
monostable multivibrator, the contents of these registers are retained without being rewritten by CRCOK, etc.
• The CXD2500B permits the peak detection register to be connected to the shift-in of the 80-bit P/S register.
For Ring Control 1, the input and output are short-circuited during peak meter and level meter mode.
For Ring Control 2, the input and output are short-circuited during peak meter mode only.
The Ring Controls are arranged in this way in order for the registers to be reset each time their contents are
read in the level meter mode, while preventing destructive read in the peak meter mode.
To enable this control, 96 clock pulses must be input to the peak meter mode.
• As afore mentioned, in the peak meter mode, the absolute time following the generation of a peak value is
stored.
These operations are shown in Time chart 2-3.
Note: To perform the above operations, the duration of the clock pulse input to SQCK must be between 750ns
and 120 µs for both “High” and “Low”.
—26—
CXD2500BQ
Timing Chart 2-1
Internal
PLL c lock
4.3218±∆MHz
WFCK
SCOR
EXCK
750ns max
SBSO
S0·S1
Q
R
WFCK
SCOR
EXCK
SBSO
S0·S1 Q R S T U V W S0·S1
Same
P1
QR S T U VW
P1
Same
Subcode P. Q. R. S. T. U. V. W Read Timing
—27—
P2
P3
SUB-Q
Block Diagram 2-2
SI
(ASEC)
LD
8
80 bit P/S Register
8
80 bit S/P Register
LD
SUBQ
LD
—28—
SO
LD
LD
Peak detection
8
SI
8
Ring control 2
SHIFT
8
LD
16
16 bit P/S register
Monostable
multivibrator
LD
LOAD CONTROLE
CRCC
8
SHIFT
8
Mix
CRCF
8
ADDRS CTRL
LD
Ring control 1
8
(AMIN)
Order
Inversion
ABS time load control
for peak value
H G F E D C B A
A B C D E F G H
SIN
(AFRAM)
SQSO
SQCK
SO
CXD2500BQ
LD
—29—
SQSO
SQCK
SQCK
SQSO
SCOR
WFCK
Timing Chart 2-3
CRCF
Monostable
multivibrator
(Internal)
CRCF 1
1
3
300ns max
3
2
1
ADR1
CRCF 1
ADR2
ADR3
CTL0
When SQCK=High, 270 to 400µsec
Register load forbidder
94
Determined by mode
93
92
91
80 or 96 Clock
750ns to 120µs
Order
Inversion
ADR0
2
95
CTL1
96
CTL2
97
CTL3
CRCF 2
98
CXD2500BQ
CXD2500BQ
§3
Other Functions
§3-1 Channel Clock Regeneration Using Digital PLL Circuit
• Demodulation of regenerated EFM signals using an optical system requires the use of channel clock pulses.
The EFM signal to be demodulated has been modulated into an integer multiple of the channel clock period
T, ranging from 3T to 11T.
To read the information conveyed by the EFM signal, it is essential to correctly recognize the integral value;
hence, the need to use channel clock pulses.
In an actual CD player, the pulse width of the EFM signal will vary, affected by fluctuations of the disc
rotation. For this reason, it is necessary to use a PLL in regenerating channel clock pulses.
Figure 3-1 shows a block diagram of the 3-stage PLL contained in the CXD2500B.
• The 1st-stage PLL is used for vari-pitch regeneration. To use this PLL, LPF and VCO are necessary as
external parts.
The minimum pitch variable possible is 0.1 %. The output of this 1st-stage PLL is used as the standard for
all the clock pulses used in the LSI.
When vari-pitch control is not in uses, connect the output pin of XTAO to VCKI.
• The 2nd-stage PLL generates high frequency clock pulses necessary for the 3rd-stage digital PLL.
• The 3rd-stage comprises a digital PLL used to regenerate the actual channel clock pulses. It realizes a
capture range of ±150 kHz (normal conditions) or more.
• The digital PLL features a secondary loop. It is controlled through the primary loop (phase) secondary loop
(frequency).
When FLFC=1, the secondary loop can be turned off.
• When high frequency components such as 3T, 4T, are deviated, turning off the secondary loop will provide
better play ability.
• However, the capture range will be 50 kHz.
—30—
CXD2500BQ
Block Diagram 3-1
16,9344MHz
(384Fs)
1/1000
1/4
Phase comparator
OSC
X'Tal
XTSL
1/4
1/1000+n
VPCO
LPF
VCO
19. 78 to 13.26MHz
VCKI
2/1 MUX
Vari-pitch
Up down counter
n=-217 to 168
Microcomputer control Vari-pitch
Phase comparator
I/M
I/N
PCO
FILI
FILO
VCO
Digital PLL
RFPLL
D2500B
—31—
CLTV
CXD2500BQ
§3-2 Frame Sync Protection
• During CD player operation at normal speed, Frame Sync is recorded approximately once every 136 µs (at
7.35 kHz).
This signal can be used to identify the data within each frame. When Frame Sync cannot be recognized, the
data also cannot be identified; as a result, it is treated as an error. Therefore, correct Frame Sync
recognition is very important to ensure high play ability for the CD player.
• The CXD2500B employs window protection, front protection and rear protection to realize a powerful Frame
Sync protection. The CXD2500B offers two window widths, one for use when the player is subjected to
rotational disturbance and the other for use without such disturbance (WSEL=0/1).
The front protection counter is fixed at 13 and the rear protection counter at 3. Therefore, during normal play
back, when the frame sync cannot be detected due to damages on the disc. If the number to frames with
undetected Frame Sync exceeds 13, the window is released and the Frame Sync signal are re-synchronized.
If no Frame Sync is correctly detected in 3 successive frames immediately after Frame Sync resynchronization performed following a window release, the window is released at once.
§3-3 Error Correction
• On CDs, each data unit (8 bits) is formatted so that it is contained in two correction codes, C1 and C2. C1
consists of 28 bytes of information and 4-byte parity, whereas C2 is made up of 24 bytes of information and
4-byte parity. Both C1 and C2 comprise a read Solomon code with a minimum distance of 5.
• C1 realizes double corrections and C2 realizes quadruple corrections, both by the refined superstrategy
method.
• To prevent erroneous C2 corrections, C1 pointer based on the conditions of C1 error, EFM signal play back,
and player operation during C1 operation is attached to the corrected data.
• The status of error correction can be monitored from outside the LSI. It is indicated as shown in Table 3-2.
• When C2 pointer is High, this signifies uncorrectable data error. The data are either previous data held
subsitute the error, or an average value interpolation.
MNT3
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
MNT2
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
MNT1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
MNT0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
C1:
C1:
C1:
C1:
C1:
C1:
C2:
C2:
C2:
C2:
C2:
C2:
C2:
Description
No error detected.
C1 pointer reset.
1 error corrected.
C1 pointer set.
—
—
No error detected.
C1 pointer set.
1 error corrected.
C1 pointer set.
2 errors corrected.
C1 pointer set.
Uncorrectable error.
C1 pointer set.
No error detected.
C2 pointer reset.
1 error corrected.
C2 pointer reset.
2 errors corrected.
C2 pointer reset.
3 errors corrected.
C2 pointer reset.
4 errors corrected.
C2 pointer reset.
—
Uncorrectable error.
C1 pointer copied.
Uncorrectable error.
C2 pointer set.
Table 3-2 Indication of error correction status
—32—
CXD2500BQ
Timing Chart 3-3
Normal - speed PB
400 to 500nsec
RFCK
t=Dependent on error
condition
MNT3
C2 correction
C1 correction
MNT2
MNT1
MNT0
Strobe
Strobe
C4M
MNT0 to 3
Valid
Valid
Invalid
§3-4 DA Interface
• The CXD2500B has two modes of DA interface.
a) 48-bit slot interface
This is an MSB-first interface made up of LRCK signals with 48-bit clock cycles per LRCK cycle. While
the LRCK signal is High, the data going through this interface is of the left channel.
b)
64-bit slot interface
This is an LSB-first interface made up of LRCK signals with 64-bit clock cycles per LRCK cycle. While
the LRCK signal is Low, the data going through this interface is of the left channel.
—33—
—34—
DA16
WDCK
DA15
(4.23M)
LRCK
(88.2K)
1
2
3
R0
L ch MSB (15)
1 2
5
L ch MSB (15)
4
48 bit slot Double-Speed Playback
DA16 R0
WDCK
DA15
(2.12M)
LRCK
(44.1K)
6
48 bit slot Normal-Speed Playback PSSL=L
Timing Chart 3-4
7
8
9
L14
10
L13
11
L12
12
L0
24
L11
L9
R ch MSB
L10
L8
L7
L6
L5
L4
L3
L2
L1
L0
24
RMSB
CXD2500BQ
—35—
DA 14
DA 13
(5.64M)
DA 12
(88.2K)
DA 14
DA 13
(2.82M)
DA 12
(44.4K)
2
4
5
R ch LSB (0)
3
L15
1
2
4
5
R ch LSB (0)
3
64 Bit slot Double–Speed PB
1
6
7
64 Bit slot Normal Speed PB PSSL=L
Timing Chart 3-5
8
10
9
10
11
12
15
13
14
1
15
2
3
20
4
1
5
6
2
7
3
20
8
25
4
6
7
9
30 31 32
8
10
11
12
9 10 11 12 13 14 15 L ch LSB
5
13
30
32
14 R15
31
L ch LSB (0)
CXD2500BQ
CXD2500BQ
§3-5 Digital Out
There are three digital-out formats: type 1 for use at broadcasting stations, type 2, form 1 for use in general
civil applications, and type 2, form 2 for use in software production. The CXD2500B supports type 2, form 1.
The clock accuracy for the channel status is automatically set at Level II when the X'tal clock is used, or
Level III when vari-pitch control is made.
CRC checks are conducted on the Sub-Q data on the first 4 bits (bits 0-3). The data is input only after two
checks are passed in succession.
The X'tal clock is set to 34 MHz, and variable pitch is reset. When D out is output at DSPB=1, set MD2 to 0
and turn off D out 34.
Digital Out C bit
0
1
2
0
16
3
From sub-Q
ID0 ID1 COPY Emph
0
0
0
0
4
5
6
7
8
9
10
11
12
13
14
15
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0/1
0
0
32
48
0
176
Bits 0-3: Sub-Q control bits required to pass the CRC twice in succession.
bit 29: Varipitch: 1 X'tal: 0
Table 3-6 Digital Out C bits
§3-6 Servo Auto Sequencer
The servo auto sequencer controls a series of operation including auto-focusing and track jumping. When an
auto sequence command is received from CPU, the servo auto sequencer automatically executes autofocusing, 1-track jumping, 2N track jumping and M track moving.
During auto sequence execution (X Busy=Low), as SSP (servo signal processing LSI) is used exclusively,
commands from CPU are not transferred to SSP. Instead, the commands can be sent to CXD2500B.
To make this servo auto sequencer usable, connect a CPU, RF and SSP to the CXD2500B as shown in
Figure 3-7 and set A.SEQ ON-OFF of Register 9 to ON.
When the CLOK changes from Low to High while XBUSY is at Low, from that point on to a maximum of 100
µsec, X BUSY does not become High.
Due to the monostable multivibrator which is reset when CLOK is Low (XBUSY=Low), transfer of erroneous
data to SSP is prevented when XBUSY changes from Low to High.
—36—
CXD2500BQ
(a)
Auto Focus ($47)
In auto focus operation, ‘focus search up’ is performed, FOK and FZC are checked, and the focus servo
is turned on. When $47 is received from CPU, the focus servo is turned on through the steps shown in
Figure 3-8. Since this auto focus sequence begins with ‘focus search up,’ it requires the pickup to be
put down (focus search down) beforehand.
Blind E of Register 5 is used to eliminate chattering from FZC. The focus servo is turned on at the
trailing edge of FZC after staying High continuously for a longer period than E.
System Configuration for Auto Sequencer Operation (Example)
RF
MIRR
FOK
MIRR
FOK
DATA
CLOK
XLAT
SENS
CXD2500B
SSP
C.out
SENS
DATA
CLK
XLT
CNIN
SEIN
DATO
CLKO
XLTO
Figure 3-7
—37—
Micro-computer
CXD2500BQ
Auto focus
Focus search up
Checking whether FZC has stayed High
longer than time E set in Register 5.
FOK=H
NO
YES
FZC=H
NO
YES
FZC=L
NO
YES
Focus servo ON
END
Figure 3-8 (a) Flow chart of auto focus operation
$47 latch
XLAT
FOK
SEIN(FZC)
BUSY
Command to SSP
Blind E
$03
Figure 3-8 (b) Timing chart for auto focus operation
—38—
$08
CXD2500BQ
(b)
Track Jump
Track jump operation includes 1, 10 and 2N track jumps. Do not perform this track jump unless the focus,
tracking and sled servos are on. Such steps as tracking gain up and braking are not included in this track
jump. Therefore, the commands for tracking gain up and brake ON ($17) must be issued in advance.
• 1-track jump
When a $48 is received from CPU (or a $49 from REV), the servo auto sequencer executes a FWD
(REV) 1-track jump as shown Figure 3-9. The values of blind A and brake B must be set in Register 5.
• 10-track jump
When a $4H is received from CPU (or a $4B from REV), the servo auto sequencer executes a FWD
(REV) 10-track jump as shown in Figure 3-10. The principal difference between the 1-track and 10-track
jumps is whether the sled is kicked or not. In the 10-track jump, the actuator after being kicked is braked
when CNIN has been counted 5 tracks. When the actuator has adequately slowed down as a result of
braking, the tracking and sled servos are turned on (this actuator slow-down is detected by checking
whether the CNIN period has exceeded overflow C specified in Register 5).
• 2N track jump
When a $4C is received from CPU (or a $4D from REV), the servo auto sequencer executes a FWD
(REV) 2N track jump. The number of tracks to be jumped is determined by N, set Register 7 beforehand.
The maximum permissible number is 216. In actual use, however, it is subject to limitation imposed by the
actuator.
When N is smaller than 16, the jumps are counted by means of counting CNIN signals. If N is 16 and
above, MIRR signals are counted instead of CNIN signals.
The 2N track jump sequence is basically the same as the 10-track jump sequence. The only difference
between them is that, in the 2N track jump sequence, the sled is kept moving for time D specified in
Register 6 after the tracking servo is turned on.
• M track move
When a $4E is received from CPU (or a $4F from REV), the servo auto sequencer executes a FWD
(REV) M-track move as shown in Figure 3-12. The maximum value that can be set from M is 216. The
track moves are counted in the same way as for 2N track jumps. That is, when M is smaller than 16, the
moves are counted by means of counting CNIN signals. If M is 16 and above, MIRR signals are counted
instead of the CNIN signals. In this M track move, only the sled is moved. This method is suitable for a
large track move ranging from several thousand to several tens of thousand tracks.
—39—
CXD2500BQ
1 Track
Track Kick
Sled servo
(REV kick is made for REV jump.)
WAIT
(Blind A)
CNIN=
NO
YES
Track REV
Kick
(FWD kick is made for REV jump.)
WAIT
(Brake B)
Track sled
Servo ON
END
Figure 3-9 (a) Flow chart of 1-track jump
$48 (REV=$49) latch
XLAT
CNIN
BUSY
Blind A
Commands to SSP
$28 ($2C)
Brake B
$2C ($28)
Figure 3-9 (b) Timing chart for 1-track jump
—40—
$25
CXD2500BQ
10 Track
Track, Sled
FWD Kick
WAIT
(Blind A)
CNIN=
5?
(5 CNINs are counted.)
NO
YES
Track, REV
FWD Kick
Checking whether the CNIN period has
exceeded the value of overflow C.
C=Overflow?
NO
YES
Track, Sled
Servo ON
END
Figure 3-10 (a) Flow chart of 10-track jump
$4A (REV=$4B) latch
XLAT
CNIN
BUSY
Blind A
Commands to SSP
CNIN 5count
$2A ($2F)
Overflow C
$2E ($2B)
Figure 3-10 (b) Timing chart for 10-track jump
—41—
$25
CXD2500BQ
2N Track
Track, Sled
FWD Kick
WAIT
(Blind A)
For the first 16 times CNIN is counted.
After that MIRR is counted.
CNIN (MIRR) =N
NO
YES
Track, REV
Kick
C=Overflow
NO
YES
Track Servo
ON
WAIT
(Klick D)
Sled Servo
ON
END
Figure 3-11 (a) Flow chart of 2N track jump
$4C (REV=$4D) latch
XLAT
CNIN
(MIRR)
BUSY
Blind A
Commands to SSP
$2A ($2F)
Kick D
CNIN (MIRR)
N count
Overflow
$2E ($2B)
$26 ($27)
Figure 3-11 (b) Timing chart for 2N track jump
—42—
$25
CXD2500BQ
M Track move
Track Servo OFF
Sled FWD Kick
WAIT
(Blind A)
CNIN is counted for M<16, MIRR
is counted for M≥16.
CNIN (MIRR) =M
NO
YES
Track, Sled
Servo ON
END
Figure 3-12 (a) Flow chart of M track move
$4E (REV=$4F) latch
XLAT
CNIN
(MIRR)
BUSY
Blind A
Commands to SSP
CNIN (MIRR) M count
$22 ($23)
$25
Figure 3-12 (b) Timing chart for M track move
—43—
CXD2500BQ
§3-7 Digital CLV
The digital CLV is a digital spindle servo, of which its block diagram is shown in Figure 3-14. It is capable of
outputting MDS or MDP error signals by the PWM method after raising the sampling frequency up to 130 kHz
based on the normal speed in the CLVS, CLVP and other modes. It also permits gain setting.
Digital CLV
Gain
CLVS U/D
MDS Error
MDP Error
0, –6dB
Measure
Measure
CLV P/S
Over Sampling
Filter-1
2/1 MUX
Gs(Gain)
GP(Gain)
CLV P
1/2
+
Mux
CLV S
CLV – P/S
Over Sampling
Filter-2
Noise Shape
KICK, BRAKE STOP
Modulation
MDP
Mode Select
MDS
DCLVMD
Figure 3-14 Block diagram
—44—
CXD2500BQ
§3-8 Asymmetry correction
Block diagram and circuit example are shown on Fig. 3-15.
D2500B
28
ASYE
ASYO
RF
24
R1
27
R1
R2
R1
ASYI
26
R1
25
BIAS
R1
R2
=
2
5
Figure 3-15 Asymmetry correction application circuit example
—45—
CXD2500BQ
Application Circuit
R1
C9
5
4
3
2
1
FESRCH
FEO
FLB
FGD
FS3
VC
FE
SENS
LDON
FOK
MUTE
SQCK
RV2
FOK
BCLK (64)
LRCK (64)
GTOP
RV1
FSW
SENS
RF
1
XRST
DATA (64)
GND
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65
DATA
XRST
BCLK (64)
TE
MIRR
2
FOK
3
MON
MOP
C17
4
LOCK
MOS
AVSS
CLTV
VDD
GND GND
C15
5
22
RF
AVDD
DATA (64)
GND
C11
C16
6
NC
VCOO
DVCC 3 6
8
NC
VCOI
13
9
14
NC
TEST1
15
VPCO
10
16
VCKI
FILO
PDO
17
PCO
FILI
12
18
11
7
34
33
DFCT
19
VSS
NC
35
CC2
CC1
FOK
30
31
EFM 3 2
ASY
DFCT
27
20
23
21
SUBQ
CLOK
WDCK (48)
GND
6
MIRR 2 9
SENS
25
26
COUT
XRST
DGND 2 8
CP
CB
GND
7
TGU
XLT
DATA
48 47 46 45 44 43 42 41 40 39 38 37
8
CNIN
SEIN
24
C4M
C16M
DOUT
MO2
EMPH
WFCK
SBSO
SCOR
54
56
57
58
59
61
62
63
64
FSTT
53
55
60
XTAI
XTSL
XTAO
MNT3
RADF
MNT2
MNT1
MNT0
APTL
APTR
44
45
47
48
49
50
42
46
51
C2PO
43
52
RFCK
41
VSS
GFS
PLCK
WFCK
DOUT
PLCK
GFS
RFCK
RAOV
GND
TRACK-D
GND
FOCUS-D
C10
9
NC
PSSL
GND
GND
MNT0
MNT1
MNT2
MNT3
GND
STTP
UGFS
—46—
GND
SLED-D
GND
C23
C26
RFO
13 14 15 16 17 18 19 20 21 22 23 24
R4 R3
DATO
25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
200p
GND
GND
WDCK
GND
GND
C2PO
MUTE
SPIND-D
GND
RFI
CLK
MUTE
ASYE
VCC
V0
VCC
DVee
DIRC
LOCK
GFS
CLK
XLT
VDD
TG2
AVCC
TAO
TA-
CXA1372Q
AVee
XLAT
DATA
CXD2500BQ
LRCK (48)
10
11
12
C27
GND
GND
GND GND GND
GND
C14
TE
TZC
SSTOP
SSTOP
GND
R2
R7
C28
R6
R11
C35
GND
GND
R12
AVDD
FE
TE
RF
LDON
C13
TDFCT
ISET
R13
VCC
GND
R10
R14
Vee
SL-
SQSO
EXCK
XUGF
ATSC
FSET
SCOR
SQCK
XLTO
GND
FE
FZC
VCC
MIRR
CLKO
BIAS
FD
GND
R5
R9
GND
GND
GND
C12
FDFCT
SL+
SLO
GND
GND
GND
GND
ASTI
ASTO
GND
1M
TD
SLD
SPD
BCLK
DATA
LRCK
DEMP
Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for
any problems arising out of the use of these circuits or for any infringement of third party and other right due to same.
CXD2500BQ
Package Outline
Unit : mm
CXD2500BQ
80PIN QFP (PLASTIC)
23.9 ± 0.4
+ 0.1
0.15 – 0.05
+ 0.4
20.0 – 0.1
64
0.15
41
65
16.3
17.9 ± 0.4
+ 0.4
14.0 – 0.1
40
A
80
+ 0.2
0.1 – 0.05
1
24
0.8
0.12
+ 0.15
0.35 – 0.1
M
0.8 ± 0.2
25
+ 0.35
2.75 – 0.15
0° to 10°
DETAIL A
PACKAGE STRUCTURE
SONY CODE
QFP-80P-L01
EIAJ CODE
∗QFP080-P-1420-A
JEDEC CODE
PACKAGE MATERIAL
EPOXY RESIN
LEAD TREATMENT
SOLDER PLATING
LEAD MATERIAL
COPPER / 42 ALLOY
PACKAGE WEIGHT
1.6g
CXD2500BQ
80PIN QFP (PLASTIC)
24.0 ± 0.3
+ 0.4
20.0 – 0.1
+ 0.
0.15 – 1
0.05
25
1
24
0.8
± 0.12 M
+ 0.15
0.35 – 0.1
16.6
80
0.7 ± 0.
40
+ 0.4
14.0 – 0.1
65
1
41
18.0 ± 0.3
64
+ 0.2
0.1 – 0.05
2.7 ± 0.1
0° to 10°
3.1 MAX
0.15
22.6
PACKAGE STRUCTURE
PACKAGE MATERIAL
EPOXY RESIN
SONY CODE
QFP-80P-L121
LEAD TREATMENT
SOLDER PLATING
EIAJ CODE
∗QFP080-P-1420-AX
LEAD MATERIAL
42 ALLOY
PACKAGE WEIGHT
1.6g
JEDEC CODE
—47—
CXD2500BQ
CXD2500BQ
QFP 80PIN (PLASTIC)
23.9 ± 0.2
∗20.0 ± 0.2
0.15 ± 0.05
15°
24
1
0.35 ± 0.1
.2
15°
25
A
4 – 1.0
∗14.0 ± 0.2
40
80
C1
4 – 0.8
0.15
M
1.45
0.8 ± 0.15
0.15
0° to 10°
DETAIL A
NOTE: Dimension “∗” does not include mold protrusion.
PACKAGE STRUCTURE
PACKAGE MATERIAL
EPOXY RESIN
SONY CODE
QFP-80P-L051
LEAD TREATMENT
SOLDER PLATING
EIAJ CODE
∗QFP080-P-1420-AH
LEAD MATERIAL
42 ALLOY
PACKAGE WEIGHT
1.6g
JEDEC CODE
—48—
1.95 ± 0.15
15°
2.94 ± 0.15
15°
0.24 ± 0.15
+ 0.20
2.7 – 0.16
17.9 ± 0.2
65
0.8
41
64