NPC SM9403BM

SM9403BM
DVDRAM Servo-amplifier LSI
NIPPON PRECISION CIRCUITS INC.
OVERVIEW
The SM9403BM is a DVDROM and DVDRAM servo preprocessor LSI, designed for double-speed format
DVDROM and DVDRAM drives.
The SM9403BM is fabricated using a BiCMOS process, and incorporates an analog signal processing circuit
that generates signals needed by the digital servo processor, a DPD signal processing circuit (DVDROM), and
a CAPA (Complementary Allocated Pit Address) detection circuit (DVDRAM) all in a single chip. It operates
from a single 5 V supply, and is available in 36-pin plastic SSOP packages.
FEATURES
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APPLICATIONS
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Double-speed DVDROM drives
Double-speed DVDRAM drives
ORDERING INFORMATION
D e vice
P ackag e
SM9403BM
36-pin SSOP
36-pin SSOP (Top View)
NC
1
36
DPDG
NC
2
35
DPDI
FER
3
34
DEFECT
FHOLD
4
33
DGND
FSUB
5
32
SCLK
ISET
6
31
SDATA
DPDD
7
30
SENB
DPDC
8
29
DVCC
DPDB
9
28
CAPSEEK
DPDA
10
27
CAPSEL
AGND
11
26
CAPIN
MMTI
12
25
AVCC
CAPAN
13
24
CAPOUT
CAPAP
14
23
CAPAREA
CAPLFC
15
22
TRP
TSUB
16
21
TROFF
THOLD
17
20
VREF2
TRE
18
19
VREF4
NPC
■
DPD signal processor
Tracking error signal output
Focus error signal output
Tracking error signal sample-and-hold
Focus error signal sample-and-hold
CAPA detection function
Track count pulse generator
Off-track detection
2V and 4V reference voltage generator
Serial interface for setting internal parameters
Sleep-mode function
Single 5 V supply
36-pin plastic SSOP
SM9403BM
■
PINOUT
NIPPON PRECISION CIRCUITS—1
SM9403BM
PACKAGE DIMENSIONS
(Unit: mm)
15.20 to 15.40
0 to 8°
0.85
0.51 ± 0.20 45°
10.11 to 10.51
7°
7.40 to 7.60
R0.63 to 0.89
0.51 to 1.01
7°
0.63 ± 0.10
0.23 to 0.32
0.10 to 0.30
2.44 to 2.64
0.80
0.29 to 0.39
BLOCK DIAGRAM
AGND
AVCC
VREF2
VREF4
DEFECT
DPDI
DPDG
FER
FHOLD
FSUB
DVCC
DGND
Voltage
reference
S/H
LPF
*
SCLK
DPDA
DPDB
Equalizer
Delay
Serial
interface
Phase
comparator
DPDC
DPDD
LPF
SDATA
SENB
ISET
SWB
TSUB
LPF
S/H
SWA
Track Pulse
Generator
*
THOLD
TRE
TRP
TROFF
*
CAPAP
CAPAN
Analog signal
processor
CAPSEEK
CAPSEL
CAPAREA
CAPOUT
CAPIN
MMTI
CAPLFC
VREF2
S/H
control
Mono-multiviblator
NIPPON PRECISION CIRCUITS—2
SM9403BM
PIN DESCRIPTION
Number
Name
I/O 1
1
NC
O
No connection
2
NC
O
No connection
3
FER
O
Focus error signal output
4
FHOLD
–
Focus error hold capacitor connection
5
FSUB
I
Focus error signal input
6
ISET
I
DPD signal equalizer, reference current set resistor connection
7
DPDD
I
DPD signal input D
8
DPDC
I
DPD signal input C
9
DPDB
I
DPD signal input B
10
DPDA
I
DPD signal input A
11
AG N D
–
Analog circuit ground
12
MMTI
I
M o n o - m ultivibrator time-constant set resistor connection
13
C A PA N
I
ID data signal differential inverting input
14
C A PA P
I
ID data signal differential non-inverting input
15
CAPLFC
–
Slice-level detect capacitor connection
16
TSUB
I
Tracking error signal input
17
THOLD
–
Tracking error hold capacitor connection
18
TRE
O
Tracking error signal output
19
VREF4
O
4V reference voltage output
20
VREF2
O
2V reference voltage output
21
TROFF
O
Off-track detect signal output. LOW when off-track.
22
TRP
O
Track count pulse output. HIGH-level pulse for land to outer tracking.
23
C A PA R E A
O
ID interval detect signal output. ID interval detected when HIGH.
24
CAPOUT
O
Outer offset ID detect signal output. Outer offset ID interval detected when HIGH.
25
AV C C
–
Analog circuit pow er supply
26
CAPIN
O
Inner offset ID detect signal output. Inner offset ID interval detected when HIGH.
27
CAPSEL
Ipd
ID interval signal input. ID interval selected when HIGH.
28
CAPSEEK
Ipd
Seek operation signal input. Seek operation selected when HIGH.
29
DV C C
–
Logic circuit pow er supply
30
SENB
I
Serial interface enable input. Enabled when HIGH.
31
S D ATA
I/O
32
SCLK
I
Serial interface clock input
33
DGND
–
Logic circuit ground
34
DEFECT
Ipd
35
DPDI
I
DPD signal hold delay set resistor connection
36
DPDG
I
DPD signal phase difference to voltage converter coefficient set resistor connection
Function
Serial interface data input/acknowledge output
Defect position signal input. Defect position indicated when HIGH.
1. I = input, Ipd = Input with built-in pull-down resistor, I/O = input/output (N-channel open-drain when output), O = output
NIPPON PRECISION CIRCUITS—3
SM9403BM
SPECIFICATIONS
Absolute Maximum Ratings
GND = 0 V
P arameter
Symbol
Condition
Rating
Unit
Supply voltage range
VCC
−0.5 to 7.0
V
Input voltage range
V IN
− 0.5 to V C C + 0.5
V
Operating temperature range
T opr
0 to 70
°C
Storage temperature range
T stg
−40 to 125
°C
Pow er dissipation
PD
250
mW
Soldering temperature
T sld
260
°C
Soldering time
tsld
10
s
Rating
Unit
Recommended Operating Conditions
GND = 0 V
P arameter
Symbol
Condition
Specifications supply voltage range
VCC
4.75 to 5.25
V
Operating supply voltage range
VCC
4.5 to 5.5
V
Operating temperature range
T opr
0 to 70
°C
Recommended External Components
Pin No.
Pin name
Component
Tolerance
4
FHOLD
1000pF capacitor
K (±10%)
ISET
47k Ω resistor
±1%
6
0.01µF capacitor
Z (+80% to −2 0 % )
12
MMTI
120k Ω resistor
±1%
15
CAPLFC
0.01µF capacitor
Z (+80% to −2 0 % )
17
THOLD
1000pF capacitor
K (±10%)
19
VREF4
0.1µF capacitor
Z (+80% to −2 0 % )
20
VREF2
0.1µF capacitor
Z (+80% to −2 0 % )
35
DPDI
47k Ω resistor
±1%
36
DPDG
33k Ω resistor
±1%
NIPPON PRECISION CIRCUITS—4
SM9403BM
DC Electrical Characteristics
VCC = 5V ± 5%, GND = 0V, Ta = 0 to 70°C
Rating
P arameter
Current
consumption 1
Symbol
Condition
Unit
min
typ
max
IC C 1
Operating mode
–
28
34
IC C 2
Sleep mode 1
–
17
21
IC C 3
Sleep mode 2
–
2.0
2.6
IC C 4
Sleep mode 3
–
–
1.0
∆I C C
IC C 1 − IC C 2
9
–
–
mA
C A P S E E K , C A P S E L , D E F E C T, SENB, SDATA,
SCLK HIGH-level input voltage
V IH
0.8V C C
–
–
V
C A P S E E K , C A P S E L , D E F E C T, SENB, SDATA,
S C L K L OW -level input voltage
V IL
–
–
0.2V C C
V
C A P S E E K , C A P S E L , D E F E C T H I G H - l evel input
current
IIH1
V IN = V C C
50
100
200
µA
S E N B , SDATA, SCLK HIGH-level input current
IIH2
V IN = V C C
–
–
3
µA
C A P S E E K , C A P S E L , D E F E C T, SENB, SDATA,
S C L K L OW -level input current
IIL
V IN = G N D
−3
–
–
µA
V C C − 0.2
–
–
V
C A PA R E A , C A P I N , C A P O U T, T R P, T R O F F
HIGH-level output voltage
VOH
I O H = −0 . 2 m A
C A PA R E A , C A P I N , C A P O U T, T R P, T R O F F
L O W -level output voltage
VOL1
IO L = 0.8mA
–
–
0.4
V
S D ATA L OW -level output voltage
VOL2
IO L = 7mA
–
–
1.0
V
1. 33k Ω resistor connected between DPDG and AG N D
47k Ω resistor connected between DPDI and AG N D
120k Ω resistor connected between MMTI and AG N D
47k Ω resistor connected between ISET and AG N D
1000pF capacitor connected between FHOLD and AG N D
1000pF capacitor connected between T H O L D a n d AG N D
0.1µF capacitor connected between VREF4 and AG N D
0.1µF capacitor connected between VREF2 and AG N D
0.01µF capacitor connected between CAPLFC and AG N D
0.01µF capacitor connected between ISET and AG N D
C A PA P, CAPA N , D P DA , D P D B, D P D C, D P D D, FSUB, TSUB connected to VREF2 or other 2V supply.
S E N B , SDATA, SCLK connected to GND; All other pins (excluding supply and ground pins) open circuit.
Sleep mode 1: DPD system only in sleep condition.
Sleep mode 2: All blocks except reference supply voltage generator in sleep condition.
Sleep mode 3: All blocks in sleep condition.
NIPPON PRECISION CIRCUITS—5
SM9403BM
Focus Sample-and-Hold, Low-pass Filter Characteristics (FSUB → FER)
VCC = 5V ± 5%, GND = 0V, Ta = 0 to 70°C, FSUB and FER signals in phase
Rating
P arameter
Condition
Unit
min
typ
max
FSUB input signal range
VREF2 reference
−1.25
0
+1.25
V
FER output voltage range
VREF2 reference
−1.25
0
+1.25
V
FER output offset voltage
VREF2 reference, V IN = V R E F 2
–
–
±8.0
mV
FER output offset voltage temperature drift
VREF2 reference
–
–
±45
µV/ °C
FER output signal slew rate
LPF off
1
–
–
V/µs
FER output load regulation
IO U T = ±3mA, V IN = V R E F 2
–
–
±10
mV
FSUB input impedance
100
–
–
kΩ
FER output signal gain
−0.17
0
+0.17
dB
LPF off (FFE = HIGH)
500
–
–
LPF on (FFE = LOW )
115
160
230
FER output signal bandwidth 1
V IN = 1.5Vp-p,
−3dB from DC
kHz
FER output gain peaking 1
DC to −3dB frequency
−3
–
+0.5
dB
Hold time FER output droop characteristic
V IN = 200mVp-p, C F H O L D = 1000pF
–
–
0.025
%/µs
S/H acquisition time
∆V IN = 200mV, target value ± 10%
–
–
1
µs
FER output hold error
With respect to the previous value
–
–
±4
mV
1
–
–
MΩ
Pow er-down state FER output impedance
1. C L = 20pF, R L = 500 Ω
Tracking Sample-and-Hold, Low-pass Filter Characteristics (TSUB → TRE)
VCC = 5V ± 5%, GND = 0V, Ta = 0 to 70°C, TSUB and TRE signals in phase
Rating
P arameter
Condition
Unit
min
typ
max
TSUB input signal range
VREF2 reference
−1.25
0
+1.25
V
TRE output voltage range
VREF2 reference
−1.25
0
+1.25
V
TRE output offset voltage
VREF2 reference, V IN = V R E F 2
–
–
±8.0
mV
TRE output offset voltage temperature drift
VREF2 reference
–
–
±45
µV/ °C
TRE output load regulation
IO U T = ±3mA, V IN = V R E F 2
–
–
±10
mV
TSUB input impedance
100
–
–
kΩ
TRE output signal gain
−0.17
0
+0.17
dB
TFE = HIGH
24
35
50
TFE = LOW
115
160
230
TRE output signal bandwidth 1
V IN = 1.5Vp-p,
−3dB from DC
kHz
TRE output gain peaking 1
DC to −3dB frequency
−3
–
+0.5
dB
Hold time TRE output droop characteristic
V IN = 200mVp-p, C T H O L D = 1000pF
–
–
0.025
%/µs
S/H acquisition time
∆V IN = 200mV, target value ±10%
–
–
1
µs
TRE output hold error
With respect to the previous value
–
–
±4
mV
1
–
–
MΩ
Pow er-down state TRE output impedance
1. C L = 20pF, R L = 500 Ω
NIPPON PRECISION CIRCUITS—6
SM9403BM
DPD Error Signal Detector Characteristics (DPDA/DPDB/DPDC/DPDD → TRP)
VCC = 5V ± 5%, GND = 0V, Ta = 0 to 70°C
Rating
P arameter 1
D P D A/DPDB/DPDC/DPDD input voltage
range
Condition
typ
max
−0.55
–
+1
V
1
–
–
MΩ
–
–
±0.17
dB
D G 2 = L OW
1.2
1.6
2.3
DG2 = HIGH
1.8
2.2
2.9
D G 2 = L OW
5.5
6.1
6.6
DG2 = HIGH
6.1
6.7
7.2
Peak gain frequency (EQE = HIGH)
3.75
5.0
6.25
−3dB frequency (EQE = LOW )
11
22
33
fpeak , (A + C) vs. (B + D)
–
–
±1.5
Time constant 1
D G 2 = L OW
56
84
109
Time constant 2
DG2 = HIGH
17
24
32
–
–
±2
VREF2 reference
D P D A/DPDB/DPDC/DPDD input
impedance
Signal gain relative accuracy
Unit
min
Gain relative to DPDA , D P D B, D P D C,
DPDD inputs
1MHz setting
Equalizer gain
dB
5MHz setting
Equalizer frequency response
Equalizer frequency response relative
accuracy
A C coupling time circuit −3dB frequency
MHz
%
kHz
A C coupling time constant relative
accuracy
−3dB frequency, (A + C) vs. (B + D)
Delay control range
See table 4.
Phase difference detector minimum time
DG1 = DG2 = LOW
2
–
–
ns
Phase difference detector maximum time
DG1 = DG2 = HIGH
–
–
1
µs
Phase difference detector minimum
repeat time
Input pulse interval
120
–
–
ns
Phase difference to voltage conversion
coefficient
DG1 = DG2 = LOW
–
See table 5.
typ ± 20%
mV/ns
–
See table 8.
±1
dB
Phase difference to voltage conversion
coefficient change accuracy
See table 4.
%
ns
Phase difference output offset voltage
VREF2 reference
–
–
±0.1
V
Phase difference output offset voltage
temperature drift
VREF2 reference
–
–
±570
µV/°C
–
–
1
µs
DEFECT signal response time
D P D e n a ble response time
D P E fl a g
–
–
2
µs
Abnor mal waveform TRP droop
characteristic
V O U T = V R E F 2 ± 200mV, VREF2 reference
–
–
0.1
%/µs
TRP output voltage range
VREF2 reference
−1.25
0
+1.25
V
TRP output signal frequency response
−3dB frequency
500
–
–
kHz
1. The tracking error signal TRE is positive with respect to VREF2 if the (DPDA + DPDC) signal phase difference is leading.
The detected phase difference is the difference between the point when one internal comparator output changes (from CMA and CMB both HIGH or
both LOW) until the second output changes before the first changes again. The phase difference is conver ted to a voltage and sampled for output.
Other signals are held constant in the output stage when a phase difference is detected.
NIPPON PRECISION CIRCUITS—7
SM9403BM
Header Position Detector Characteristics (CAPAP/N → CAPAREA, CAPIN, CAPOUT)
VCC = 5V ± 5%, GND = 0V, Ta = 0 to 70°C
Rating
P arameter
Condition
Unit
min
typ
max
1
–
3
V
13
–
–
MHz
–
See table 9.
typ ± 15%
V
typ − 5 %
See table 10.
typ + 45%
µs
M o n o - m ultivibrator time constant switching
accuracy
–
–
±5
%
M o n o - m ultivibrator time-constant block
interval accuracy
–
–
±2.5
%
–
–
15
ns
C A PAP/N input voltage range
Analog signal processor frequency
response
V IN = V R E F 2 ± 0.5V, −3dB from DC
Analog signal quantization slice level
M o n o - m ultivibrator time constant
C A P I N , C A P O U T, CAPAREA output rise
time and fall time
C L = 20pF
Sample-and-Hold Control Signal Generator Characteristics
VCC = 5V ± 5%, GND = 0V, Ta = 0 to 70°C
Rating
P arameter
FER, TRE output response time 1
Condition
Unit
min
typ
max
M o n o - m ultivibra t o r / C A P S E L / C A P S E E K →
FSHCNT/TSHCNT
–
–
100
ns
Serial interface (HRE, FHE, THE, HAE) →
FSHCNT/TSHCNT
–
–
2
µs
1. F S H C N T a n d TSHCNT are the focus and tracking sample-and-hold internal control signals, respectively.
Tracking Error Signal Switching Characteristics (SWA, SWB)
VCC = 5V ± 5%, GND = 0V, Ta = 0 to 70°C
Rating
P arameter
Switching response time
Condition
Serial interface timing
Unit
min
typ
max
–
–
1
µs
NIPPON PRECISION CIRCUITS—8
SM9403BM
Track Count Pulse Generator Characteristics (TSUB → TRP, TROFF)
VCC = 5V ± 5%, GND = 0V, Ta = 0 to 70°C
Rating
P arameter
Condition
Unit
min
typ
max
TSUB input signal range
VREF2 reference
−1.25
–
+1.25
V
TSUB signal limiter voltage level
VREF2 reference
±1.0
–
–
V
TSUB signal amplifier gain
f = 5kHz
5.83
6.0
6.17
dB
typ − 1 5 %
See table 15
typ + 15%
mV
typ − 1 0 %
See table 16
typ + 10%
mV
Quantization level offset set value
TRP output comparator
hysteresis 1
TRP output comparator hysteresis
response time
Minimum hysteresis, target value ± 10%
–
–
600
ns
TRP output comparator hysteresis
switching response time
Minimum ↔ maximum hysteresis value
–
–
2
µs
typ − 1 0 %
See table 17
typ + 10%
mV
–
–
5
µs
T R OFF output comparator window
T R OFF output comparator window
switching response time
Minimum ↔ maximum window value
1. TRP has the same polarity as TRE (i.e. TRP is HIGH when TRE > VREF2).
T R OFF is HIGH when the input signal is inside the window , and LOW when outside the window .
Reference Voltage Generator Characteristics (VREF2, VREF4)
VCC = 5V ± 5%, GND = 0V, Ta = 0 to 70°C
Rating
P arameter
Condition
Unit
min
typ
max
3.84
4.0
4.16
V
1.92
2.0
2.08
V
–
–
±400
µV/°C
–
–
±200
µV/°C
–
–
±6
mV
–
–
±3
mV
IO U T = 0 to 8mA
–
–
−20
mV
IO U T = 0 to ±5mA
–
–
±10
mV
V C C = 5V, IO U T = 0
–
–
±20
mV
Relative output voltage temperature drift
V C C = 5V, T a = 0 to 70°C , IO U T = 0
–
–
±10
µV/°C
Relative output-voltage supply-voltage
dependency
V C C = 5V ± 5%, T a = 25°C , IO U T = 0
–
–
±1
mV
V R E F 4 p ow er-down output impedance
13
–
–
kΩ
V R E F 2 p ow er-down output impedance
1
–
–
MΩ
VREF4 output voltage
V C C = 5V, T a = 25°C , IO U T = 0
VREF2 output voltage
VREF4 output voltage temperature drift
VREF2 output voltage temperature drift
V C C = 5V, T a = 0 to 70°C , IO U T = 0
VREF4 output voltage supply voltage
dependency
VREF2 output voltage supply voltage
dependency
VREF4 output voltage load regulation
VREF2 output voltage load regulation
Relative output voltage
accuracy 1
V C C = 5V ± 5%, T a = 25°C , IO U T = 0
V C C = 5V,
T a = 25°C
1. D e fi ned as (VREF2 − (VREF4 ÷ 2)).
NIPPON PRECISION CIRCUITS—9
SM9403BM
Serial Interface Characteristics (SCLK, SDATA, SENB)
VCC = 5V ± 5%, GND = 0V, Ta = 0 to 70°C
Rating
P arameter
Symbol
Condition
Unit
min
typ
max
SCLK pulse cycle
tc y S C K
100
–
–
ns
SCLK HIGH-level pulsewidth
tw h S C K
40
–
–
ns
S C L K L OW -level pulsewidth
tw l S C K
40
–
–
ns
SENB setup time
ts S E N
20
–
–
ns
SENB hold time
th S E N
40
–
–
ns
S D ATA setup time
ts S DA
15
–
–
ns
S D ATA hold time
th S D A
15
–
–
ns
time 1
ts AC K
0
–
20
ns
th AC K
–
–
50
ns
ti n S E N
100
–
–
ns
A CK setup
A CK hold
time 1
SENB inter val
1. A CK is the acknowledge output (n-channel open-drain). LOW -level output when the data received is valid.
S D ATA load capacitance is 15pF.
tinSEN
SENB
tsSEN twhSCK twlCLK
thSEN
tcySCK
SCLOCK
thACK
tsSDA thSDA
SDATA
Controller
SDATA
Port
bit 0
LSB
tsACK
bit 1
bit 15
MSB
ACK
High Impedance
NIPPON PRECISION CIRCUITS—10
SM9403BM
FUNCTIONAL DESCRIPTION
Serial Interface
The SM9403BM uses a serial interface comprising 5
ports to control and set all functions. The address and
bit configuration of each port is shown in table 1
Table 1. Port address and bit configuration1
Bit nu m b e r
15
14
13
12
11
10
9
8
7
6
5
Data
4
3
2
1
0
A d dress
MSB
LSB
DPE
HAE
FFE
TFE
SWB
SWA
SL2
SL1
×
LOW
LOW
LOW
HIGH
LOW
×
×
OF3
OF2
OF1
WD2
WD1
HS3
HS2
HS1
×
LOW
LOW
LOW
HIGH
HIGH
×
×
THE
FHE
HRE
MM2
MM1
LS3
LS2
LS1
×
LOW
LOW
HIGH
LOW
LOW
×
×
EQE
CG3
CG2
CG1
DL4
DL3
DL2
DL1
×
LOW
LOW
HIGH
LOW
HIGH
×
×
TS3
TS2
TS1
–
–
–
DG2
DG1
×
LOW
LOW
HIGH
HIGH
LOW
×
×
1. × = don’t care, – = unassigned
Serial data is input on SDATA with the LSB first, in
sync with the falling edge of the SCLK clock. After
the 16th SCLK falling edge and 16 bits of valid data
has been input, the SDATA n-channel open-drain
output goes LOW as an acknowledge signal.
If the number of SCLK cycles which occur when
SENB (serial interface enable) is HIGH is less than
16, the received data is ignored and the internal port
is not updated. If the number of SCLK cycles is
greater than 16, the data is still considered value up
to the 16th SCLK falling edge, the data is latched
into the internal port, and the acknowledge signal is
output. The acknowledge signal is held until SENB
goes LOW again.
Focus Sample-and-Hold/Low-pass Filter (FSUB → FER)
This stage, the signal which is generated from the
header position detector signal samples and holds the
focus error signal. The output then passes through a
low-pass filter. This low-pass filter can be turned ON
or OFF using the serial interface control bit FFE.
Table 2. Focus low-pass filter ON/OFF control
FFE
L o w-pass filter 1
LOW
ON
HIGH
OFF
1. Default is ON
Tracking Sample-and-Hold/Low-pass Filter (TSUB → TRE)
This stage, the signal which is generated from the
header position detector signal samples and holds the
tracking error signal. The output then passes through
a low-pass filter. This low-pass filter cutoff frequency
can be switched using the serial interface control bit
TFE.
Table 3. Tracking low-pass filter cutoff frequency
TFE
L o w-pass filter 1
LOW
fC = 160kHz
HIGH
fC = 35kHz
1. Default is 160kHz
NIPPON PRECISION CIRCUITS—11
SM9403BM
DPD Error Signal Detector (DPDA/DPDB/DPDC/DPDD → TRP)
This stage compares the DPD signals, passes the
comparator output through a low-pass filter to obtain
the DPD tracking error signal.
The phase comparator incorporates a detector function which prevents abnormal waveform signals getting to the output by holding the output constant.
The DPD signals are first added, (DPDA + DPDC)
and (DPDB + DPDD), then passed to an equalizer. A
relative time delay is added for offset correction. The
signals are then converted to a pulse waveform by
comparators with hysteresis characteristics.
In addition, serial interface control bit DPE and input
DEFECT can be used to force the tracking error signal to the reference voltage VREF2. These controls
can be used when powering up a system or to prevent
output saturation from occurring during periods
when the input signal is unstable.
The phase comparator then compares the phase of
the pulse waveforms to obtain a time signal equivalent to the tracking error. The time signal is then converted to a voltage.
The converted voltage is passed to the output stage,
undergoes sampling timing compensation before
being integrated to generate the tracking error signal
output.
The relative time delay setting and time-to-voltage
conversion coefficient can be controlled using serial
interface control bits. Also, the equalizer used to
compensate for the previous stage can be turned ON
or OFF using serial interface control.
NIPPON PRECISION CIRCUITS—12
SM9403BM
Table 4. DPD delay time settings
Table 4. DPD delay time settings (Continued)
DPD delay (ns) 1
DG2
LOW
LOW
DG1
DL4
DL3
DL2
DL1
DPD delay (ns) 1
DG2
min
typ
max
DG1
DL4
DL3
DL2
DL1
min
typ
max
LOW
LOW
LOW
LOW
0
0
0
LOW
LOW
LOW
LOW
0
0
0
LOW
LOW
LOW
HIGH
−2.2
−3.0
−3.3
LOW
LOW
LOW
HIGH
−7.0
−8.5
−13
LOW
LOW
HIGH LOW
−4.2
−5.6
−6.4
LOW
LOW
HIGH LOW
−15
−17
−24
LOW
LOW
HIGH HIGH
−6.0
−8.0
−9.5
LOW
LOW
HIGH HIGH
−22
−27
−36
LOW
HIGH LOW
LOW
−7.5
−11
−13
LOW
HIGH LOW
LOW
−32
−37
−50
LOW
HIGH LOW
HIGH
−10
−14
−16
LOW
HIGH LOW
HIGH
−43
−48
−65
LOW
HIGH HIGH LOW
−12
−17
−20
LOW
HIGH HIGH LOW
−55
−62
−83
LOW
HIGH HIGH HIGH
−14
−20
−24
LOW
HIGH HIGH HIGH
−70
−78
−108
LOW
HIGH LOW
HIGH LOW
LOW
LOW
+17
+24
+29
HIGH LOW
LOW
LOW
+90
+100
+136
HIGH LOW
LOW
HIGH
+14
+20
+23
HIGH LOW
LOW
HIGH
+70
+78
+102
HIGH LOW
HIGH LOW
+12
+17
+19
HIGH LOW
HIGH LOW
+55
+61
+76
HIGH LOW
HIGH HIGH
+10
+13
+15
HIGH LOW
HIGH HIGH
+42
+47
+60
HIGH HIGH LOW
LOW
+7.5
+11
+13
HIGH HIGH LOW
LOW
+31
+36
+45
HIGH HIGH LOW
HIGH
+5.6
+7.7
+9.0
HIGH HIGH LOW
HIGH
+22
+26
+34
HIGH HIGH HIGH LOW
+3.7
+5.5
+6.2
HIGH HIGH HIGH LOW
+14
+17
+23
HIGH HIGH HIGH HIGH
+2.0
+3.0
+3.4
HIGH HIGH HIGH HIGH
+7.2
+8.2
+12
LOW
LOW
LOW
LOW
0
0
0
LOW
LOW
LOW
LOW
0
0
0
LOW
LOW
LOW
HIGH
−3.8
−4.5
−6.0
LOW
LOW
LOW
HIGH
−9.5
−11
−17
LOW
LOW
HIGH LOW
−7.0
−8.5
−11
LOW
LOW
HIGH LOW
−19
−22
−32
LOW
LOW
HIGH HIGH
−11
−13
−17
LOW
LOW
HIGH HIGH
−30
−35
−49
LOW
HIGH LOW
LOW
−16
−18
−24
LOW
HIGH LOW
LOW
−42
−48
−74
LOW
HIGH LOW
HIGH
−20
−23
−32
LOW
HIGH LOW
HIGH
−60
−67
−105
LOW
HIGH HIGH LOW
−26
−30
−42
LOW
HIGH HIGH LOW
−80
−90
−150
LOW
HIGH HIGH HIGH
−34
−38
−55
LOW
H I G H H I G H H I G H −110
−122
−205
HIGH
HIGH HIGH
HIGH LOW
LOW
LOW
+44
+49
+74
HIGH LOW
LOW
LOW
+124
+167
+210
HIGH LOW
LOW
HIGH
+33
+37
+52
HIGH LOW
LOW
HIGH
+108
+120
+194
HIGH LOW
HIGH LOW
+25
+29
+38
HIGH LOW
HIGH LOW
+80
+88
+130
HIGH LOW
HIGH HIGH
+20
+22
+29
HIGH LOW
HIGH HIGH
+58
+65
+90
HIGH HIGH LOW
LOW
+15
+17
+22
HIGH HIGH LOW
LOW
+42
+47
+64
HIGH HIGH LOW
HIGH
+10
+12
+17
HIGH HIGH LOW
HIGH
+29
+33
+45
HIGH HIGH HIGH LOW
+7.0
+7.9
+11
HIGH HIGH HIGH LOW
+18
+21
+31
HIGH HIGH HIGH HIGH
+3.6
+4.3
+5.6
HIGH HIGH HIGH HIGH
+9.0
+10
+16
1. Default is 0 ns (DL4 = DL3 = DL2 = DL1 = LOW )
The DPD delay is positive when (A+C) leads (B+D).
NIPPON PRECISION CIRCUITS—13
SM9403BM
Table 5. Phase difference to voltage converter
coefficient
CG3
CG2
CG1
C o e f fi cient
(mV/ns) 1
LOW
LOW
LOW
5.38
LOW
LOW
HIGH
7.58
LOW
HIGH
LOW
10.7
LOW
HIGH
HIGH
15.2
HIGH
LOW
LOW
21.4
HIGH
LOW
HIGH
30.3
HIGH
HIGH
LOW
42.7
HIGH
HIGH
HIGH
60.6
1. Default is 15.2 mV/ns
Table 6. Equalizer control
EQE
Equalizer 1
LOW
OFF
HIGH
ON
1. Default is OFF
Table 7. DPD output control
DPE
DEFECT
DPD output 1
LOW
×
Forced to V R E F 2
×
HIGH
Forced to V R E F 2
HIGH
LOW
Active
1. Default is VREF2 (DPE = LOW )
Table 8. DPD delay time coefficient, phase difference to voltage converter coefficient, AC coupling time constant
DG2
DG1
Phase to voltag e coefficient
(relative to values in table 5) 1
LOW
LOW
×1
LOW
HIGH
× 1/2
HIGH
LOW
× 1/4
HIGH
HIGH
× 1/8
D P D - AC coupling time
constant circuit −3dB
frequency
Selected media
8-times CD, DV D - R A M
100 kHz
4-times CD
2-times CD
25 kHz
1-times CD
1. Default is DG2 = DG1 = LOW
NIPPON PRECISION CIRCUITS—14
SM9403BM
Header Position Detector (CAPAP/N → CAPAREA, CAPIN, CAPOUT)
This stage converts a high-speed push-pull signal
(CAPAP/CAPAN) to single-ended signals, passes
the outputs through low-pass filters to form quantized logic levels which are used as reference signals.
These reference signals are level shifted to form plus
and minus signals for use by comparators. The
amount of level shift can be controlled by serial
interface control bits.
tinuous signals. This creates inner shifted header
CAPIN and an outer shifted header CAPOUT output
signals.
After quantization logic conversion, retriggerable
mono-multivibrators convert the pulse strings to con-
In addition, the single-ended signal is also passed
through a high-pass filter, which similarly converts
to quantized logic signals. Retriggerable mono-multivibrators then convert the pulse strings to continuous signals to create a header area CAPAREA signal.
The mono-multivibrator time constants are controlled by serial interface control bits.
Table 9. Slice level shift voltages
Table 11. CAPOUT/CAPIN/CAPAREA logic
LS3
LS2
LS1
L evel shift
(mV) 1
LOW
LOW
LOW
±25
LOW
LOW
HIGH
±50
LOW
HIGH
LOW
±75
LOW
HIGH
HIGH
±100
HIGH
LOW
LOW
±125
HIGH
LOW
HIGH
±150
HIGH
HIGH
LOW
±200
HIGH
HIGH
HIGH
±250
C A PA R E
A
HAE1
CAPOUT
CAPIN
LOW
LOW
Header signal
output
Header signal
output
LOW
HIGH
LOW
LOW
HIGH
LOW
Header signal
output
Header signal
output
HIGH
HIGH
Header signal
output
Header signal
output
1. Default is LOW
1. Default is ±25 mV
Table 10. Mono-multivibrator time constants
MM2
MM1
CAPOUT/CAPIN
output (µs) 1
C A PAREA (µs) 1
LOW
LOW
4
8+α
LOW
HIGH
8
16 + α
HIGH
LOW
12
24 + α
HIGH
HIGH
16
32 + α
1. Default is 4 µs and (8 + α), where α ≈ 6 × ln(2V L S /V H ), V H = input signal amplitude, V L S = slice level absolute value shown in table 9.
NIPPON PRECISION CIRCUITS—15
SM9403BM
Sample-and-Hold Control Signal Generator
This stage takes the OR-logic of the CAPIN and
CAPOUT signals, generated by the header position
detector, the CAPSEL and CAPSEEK input signals,
and the serial interface control bit HRE and uses
them to create a sample-and-hold circuit control signal SHCNT.
The SHCNT is then used in conjunction with serial
interface select bits FHE and THE to form the focus
sample-and-hold (FSHCNT) and tracking sampleand-hold (TSHCNT) signals.
Table 12. Sample-and-hold logic
CAPIN
CAPOUT
CAPSEL
CAPSEEK
HRE1
SHCNT
HIGH
×
×
LOW
HIGH
HIGH
×
HIGH
×
LOW
HIGH
HIGH
LOW
LOW
×
LOW
×
LOW
HIGH
×
×
LOW
LOW
LOW
×
HIGH
×
LOW
LOW
LOW
×
×
HIGH
HIGH
×
HIGH
×
×
LOW
HIGH
×
LOW
1. Default is LOW
× = don’t care.
Table 13. Sample-and-hold signal control logic
FHE1
THE1
FSHCNT2
TSHCNT2
LOW
×
LOW
×
×
LOW
×
LOW
HIGH
×
SHCNT
×
×
HIGH
×
SHCNT
1. Default is LOW
2. FSHCNT is the focus sample-and-hold control signal, and T S H C N T i s
the tracking sample-and-hold control signal.
× = don’t care.
Tracking Error Signal Switching (SWA, SWB)
This stage performs tracking error signal switching
during DVDRAM write/read and DVDROM and CD
playback. Switching is controlled by serial interface
control bits.
Table 14. Tracking error signal select
S WA
SWB
Tracking error
signal select 1
LOW
LOW
S/H
HIGH
HIGH
DPD
1. Default is S/H
NIPPON PRECISION CIRCUITS—16
SM9403BM
Track Count Pulse Generator (TSUB → TRP, TROFF)
This stage filters the tracking error signal through a
6th-order Butterworth low-pass filter which effectively filters off header signal leakage effects. An offset voltage is added and the signal passes through a
comparator with hysteresis to generate a track count
pulse signal output on TRP. Simultaneously, the window comparator corresponding to the tracking error
signal is output as the off-track signal on TROFF
(LOW for off-track).
Table 16. TRP comparator hysteresis
HS3
HS2
HS1
Hysteresis (mV) 1
LOW
LOW
LOW
±100
LOW
LOW
HIGH
±200
LOW
HIGH
LOW
±300
LOW
HIGH
HIGH
±400
The offset voltage, hysteresis level and window
width are controlled by serial interface bits.
HIGH
LOW
LOW
±500
HIGH
LOW
HIGH
≥ 500
Table 15. Offset voltage setting
HIGH
HIGH
LOW
≥ 500
HIGH
HIGH
HIGH
≥ 500
OF3
OF2
OF1
Offset voltag e (mV) 1
LOW
LOW
LOW
0
LOW
LOW
HIGH
−200
LOW
HIGH
LOW
−400
LOW
HIGH
HIGH
−600
HIGH
LOW
LOW
+800
HIGH
LOW
HIGH
+600
HIGH
HIGH
LOW
+400
HIGH
HIGH
HIGH
+200
1. Default is ±100 mV
Table 17. TROFF comparator window
WD2
WD1
Comparator
w i n d ow (mV) 1
LOW
LOW
±125
LOW
HIGH
±250
HIGH
LOW
±375
HIGH
HIGH
±475
1. Default is ±125 mV
1. Default is 0 mV
Sleep Mode
The SM9403BM features 3 sleep modes which can
be used when the device is not operating to signifi-
cantly reduce current consumption. The sleep modes
are controlled by serial interface bits.
Table 18. Sleep mode settings
SL2
SL1
Mode description 1
LOW
LOW
Sleep mode OFF (nor mal operation)
LOW
HIGH
DPD in sleep condition
HIGH
LOW
All except reference voltage supply in
sleep condition
HIGH
HIGH
All blocks in sleep condition
1. Default is OFF (SL2 = SL1 = LOW )
Preset Function
When power is applied or in sleep modes 2 and 3, all
serial interface flags are reset to their default values
with the exception of the sleep mode flags SL2 and
SL1 (see the section “Serial Interface”). However,
when writing data to SL2 and SL1 to cancel sleep
mode, other flags in the same data word have precedence when writing to the port.
NIPPON PRECISION CIRCUITS—17
SM9403BM
NIPPON PRECISION CIRCUITS INC. reserves the right to make changes to the products described in this data sheet in order to
improve the design or performance and to supply the best possible products. Nippon Precision Circuits Inc. assumes no responsibility fo r
the use of any circuits shown in this data sheet, conveys no license under any patent or other rights, and makes no claim that the circuits
are free from patent infringement. Applications for any devices shown in this data sheet are for illustration only and Nippon Precision
Circuits Inc. makes no claim or warranty that such applications will be suitable for the use specified without further testing or modification.
The products described in this data sheet are not intended to use for the apparatus which influence human lives due to the failure or
malfunction of the products. Customers are requested to comply with applicable laws and regulations in effect now and hereinafter,
including compliance with expor t controls on the distribution or dissemination of the products. Customers shall not expor t, directly or
indirectly, any products without first obtaining required licenses and approvals from appropriate government agencies.
NIPPON PRECISION CIRCUITS INC.
NIPPON PRECISION CIRCUITS INC.
4-3, Fukuzumi 2-chome
Koto-ku, Tokyo 135-8430, Japan
Telephone: 03-3642-6661
Facsimile: 03-3642-6698
NC9813AE
1999.09
NIPPON PRECISION CIRCUITS—18