SONY CXA2095

CXA2095S
Y/C/RGB/Sync/Deflection for Color TV
Description
The CXA2095S is a bipolar IC which integrates
the luminance signal processing, chroma signal
processing, RGB signal processing, and sync and
deflection signal processing functions for NTSC
system color TVs onto a single chip.
The following functions have been added to the
same function IC, CXA2025S.
1) Vertical sync pull-in speed switching function
2) YUV SW Y signal switching function
3) fsc output pin
48 pin SDIP (Plastic)
Absolute Maximum Ratings
(Ta = 25°C, SGND, JGND = 0V)
• Supply voltage
SVCC, JVCC –0.3 to +12 V
• Operating temperature
Topr
–20 to +75 °C
• Storage temperature
Tstg
–65 to +150 °C
• Allowable power dissipation
PD
1.5
W
• Voltages at each pin –0.3 to SVCC, JVCC + 0.3 V
Features
• I2C bus compatible
• Sync signal processing uses a countdown system
with non-adjusting H/V oscillator frequencies
• Built-in deflection compensation circuit capable of
supporting various wide modes
• Non-adjusting Y/C block filter
• Built-in AKB
• Video signal I/Os: Y/C separation input, Y/color
difference input, analog RGB input and RGB
output
• YUV SW Y signal switching function allows picture
quality adjustment for the Y signal in the same
manner as for the normal Y signal even when
Y/color difference input is selected
Operating Conditions
Supply voltage
SVCC
JVCC
9.0 ± 0.5
9.0 ± 0.5
V
V
Applications
Color TVs (4:3, 16:9)
FSCOUT
BGP
VM
HSIN
VSIN
VSFIL
IREF
JGND
CERA
AFCFIL
L2FIL
AFCPIN/HOFF
HDRIVE
JVCC
SAWOSC
VAGCSH
EWDRIVE
VDRIVE+/VPROT
VDRIVE–/VPROT
VTIM (SCP)
ABLFIL
ABLIN/VCOMP
IKIN
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
APCFIL
BLHOLD
YIN
CIN
SVCC
SCL
SDA
YUV SW
EYIN
ERYIN
EBYIN
SGND
YM
YS
RIN
GIN
BIN
RSH
ROUT
GSH
GOUT
BSH
Pin Configuration
BOUT
NC
48
XTAL
Structure
Bipolar silicon monolithic 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–
E96X20-PS
7
SDA
VSFIL
HSYNC
SEP.
44
HSIN
48
NC
JGND
D-COL
GAMMA
25
20
22
24
23
21
19
18
17
16
15
14
13
12
11
10
EYIN
9
YUVSW
6
SVCC
1
XTAL
47
FSCOUT
2
APCFIL
5
CIN
BLHOLD
VM
YIN
BLANKING BUFFER
AKB/CUTOFF/IK
DRIVE
BRIGHT
27
ERYIN
CLAMP
V ZOOMING
26
EBYIN
ABL
28
SGND
RGB CLAMP
YS SW
REF-P SW
PICTURE
29
V SAW
GEN.
30
YM
YM ATT.
Y/C MIX
WIDE
MODE
V PARA
GEN.
31
YS
YUV
CLAMP
AMP
YUV SW
32
V SAW
OSC/AGC
33
SAWOSC
RIN
CHROMA
VCO
CHROMA
DEMOD.
AXIS
H PHASE
SHIFTER
H DRIVE
34
HDRIVE
35
VAGCSH
GIN
3
HUE
36
L2FIL
H PHASE
DETECTOR
AFCPIN
/HOFF
37
EWDRIVE
BIN
CHROMA
APC
KILLER
DETECTOR
32fH VCO
39
VDRIVE+
RSH
45
COLOR
1/32
DIVIDER
PHASE
DETECTOR
CERA
40
VDRIVE–
/VPROT
GSH
4
ACC AMP
AFCFIL
38
VTIM
BSH
TOT
CLAMP
DC-TRAN
D-PIC
TIMING PULSE GEN.
V COUNT DOWN
VSYNC
SEP.
42
ABLIN
/VCOMP
BOUT
VM AMP
SHARPNESS
VSIN
43
ABLFIL
GOUT
SUBCONT
41
BGP
IREF
IREF
46
IKIN
ROUT
–2–
C-TRAP
Y DELAY
D/A
I2C BUS
DECODER
SCL
8
JVCC
Block Diagram
CXA2095S
CXA2095S
Pin Description
Pin
No.
Symbol
Equivalent circuit
Description
SVCC
1
350
XTAL
Connect a 3.579545MHz crystal oscillator.
1
200µ
SVCC
1.2k
2
APCFIL
1.2k
CR connection for the chroma APC lag-lead
filter.
2
50µ
50µ
SVCC
9µ
20k
3
BLHOLD
3
4k
20k
Capacitor connection for black peak hold of the
dynamic picture (black expansion).
1.2k
25µ
SVCC
Y signal input.
Input a 2Vp-p (including sync, 100% white) Y
signal via a capacitor. The pedestal level of the
input signal is clamped to 4.2V.
1.2k
4
YIN
4
100µ
SVCC
Chroma signal input.
Provide a bias of about VCC/2 and input a C
signal (including sync, 100% white, 2Vp-p CV
signal) with a 570mVp-p burst level.
10p
5
CIN
5
30k
35µ
6
SVCC
Power supply for the video block.
JVCC
50µ
4k
7
SCL
I2C bus protocol SCL (Serial Clock) input.
VILMAX = 1.5V
VIHMIN = 3.5V
7
10k
–3–
CXA2095S
Pin
No.
Symbol
Equivalent circuit
Description
JVCC
50µ
8
SDA
I2C bus protocol SDA (Serial Data) I/O.
VILMAX = 1.5V
VIHMIN = 3.5V
VOLMAX = 0.4V
8
SVCC
100µ
9
YUV SW
147
9
40k
10
External Y signal input.
Input a 0.7Vp-p (100 IRE) Y signal via a
capacitor. The signal is clamped to 6.5V at the
burst timing of the signal input to the sync input
(Pin 44).
EYIN
SVCC
2k
1k
11
ERYIN
Switch control for the external YUV signal input.
When YUV SW is high, the external YUV signal
is selected; when YUV SW is low, the Y/C block
signal is selected. However, when the EY-SW
register is 1, the YIN (Pin 4) input is selected for
the Y signal even if YUV SW is high.
VILMAX = 0.4V
VIHMIN = 1.0V
VIHMAX = 3.0V
10
11
40k
12
External R-Y signal input.
Input a 0.78Vp-p (color difference signal
obtained by detecting a 100 IRE, 0.7Vp-p,
100% color bar chroma signal at the orthogonal
axis) + (R-Y) signal via a capacitor. The signal
is clamped to 6.2V at the burst timing of the
signal input to the sync input (Pin 44).
12
EBYIN
External B-Y signal input.
Input a 1.0Vp-p (color difference signal obtained
by detecting a 100 IRE, 0.7Vp-p, 100% color
bar chroma signal at the orthogonal axis) + (BY) signal via a capacitor. The signal is clamped
to 6.2V at the burst timing of the signal input to
the sync input (Pin 44).
13
SGND
GND for the video block.
SVCC
YM switch control input.
When YM is high, the Y/C block signal is
attenuated by 6dB.
VILMAX = 0.4V
VIHMIN = 1.0V
VIHMAX = 3.0V
100µ
14
YM
147
14
40k
–4–
CXA2095S
Pin
No.
Symbol
Equivalent circuit
Description
SVCC
100µ
15
YS
147
15
40k
YS switch control input.
When YS is high, the RGB block signal is
selected; when YS is low, the Y/C block is
selected.
VILMAX = 0.4V
VIHMIN = 1.0V
VIHMAX = 3.0V
SVCC
200
16
17
18
RIN
GIN
BIN
Analog R, G and B signal input.
Input a 0.7Vp-p (no sync, 100 IRE) signal via a
capacitor. The signal is clamped to 5.1V at the
burst timing of the signal input to the sync input
(Pin 44).
16
17
30k
18
SVCC
Sample-and-hold for R, G and B AKB.
Connect to GND via a capacitor. When not using
AKB (manual cut-off mode), R, G and B cut-off
voltage can be controlled by applying a control
voltage to each pin. The control voltage is 4.2 ±
2V.
1k
19
21
23
RSH
GSH
BSH
19
21
23
50µ
SVCC
200
20
22
24
ROUT
GOUT
BOUT
R, G and B signal output.
2.4Vp-p is output during 100% white input.
12k
20
1100µ
SVCC
1k
25
IKIN
25
50µ
ABL control signal input and VSAW high voltage
fluctuation compensation signal input.
High voltage compensation has linear control
characteristics for the pin voltage range of about
8V to 1V.
ABL operates when the pin voltage becomes
lower than about 1.2V.
SVCC
26
ABLIN
/VCOMP
Input the signal converted from the CRT beam
current (cathode current IK) to a voltage via a
capacitor. The V blanking part is clamped to 2.7V at
the V retrace timing.
The input for this pin is the reference pulse return,
and the loop operates so that the Rch, the Gch and
Bch are all 1Vp-p. (∗For the CXA2025S, the loop
operates so that the Rch is 1Vp-p and the Gch and
Bch are 0.83Vp-p.) The Gch and Bch can be varied
by ±0.5V by the bus CUTOFF control. When not
using AKB, this pin should not be connected.
147
26
–5–
CXA2095S
Pin
No.
Symbol
Equivalent circuit
Description
SVCC
10k
27
ABLFIL
Connect a capacitor to form the LPF of the ABL
control signal.
27
1.2k
JVCC
1k
28
VTIM
(SCP)
28
10k
1k
V timing pulse output.
Outputs the timing pulse from V sync
identification to the end of V blanking. Pulses are
positive polarity from 0 to 6 [V]. During zoom
mode, the V blanking pulse which has been
expanded before and after the V sync is
superimposed and output as the 0 to 3 [V] pulse.
JVCC
720
29
VDRIVE–
/VPROT
V sawtooth wave output and Vprotect signal
input.
When a large current (3mA) is led from this pin,
the RGB outputs are all blanked and the status
is returned to the I2C bus.
30k
29
400µ
24k
JVCC
720
30
VDRIVE+
/VPROT
Outputs a V sawtooth wave of the opposite
polarity as VDRIVE–. The Vprotect function can
also be operated by this pin.
30k
30
24k
400µ
JVCC
1.4k
25µ
31
EWDRIVE
V parabola wave output.
15k
31
78k
800µ
JVCC
32
Sample-and-hold for AGC which maintains the V
sawtooth wave at a constant amplitude.
Connect to GND via a capacitor.
1.2k
VAGCSH
32
–6–
CXA2095S
Pin
No.
Symbol
Equivalent circuit
Description
JVCC
33
100
SAWOSC
Connect a capacitor to generate the V sawtooth
wave.
100
33
100µ
34
Power supply for the deflection block.
JVCC
JVCC
H drive signal output.
This signal is output with the open collector.
This pin goes high (OFF) during hold-down.
∗ For the CXA2025S, this pin is low (ON) during
hold-down.
147
35
35
HDRIVE
20k
JVCC
36
AFCPIN
/HOFF
147
10k
4.2V
60k
36
50µ
50µ
10k
JVCC
37
L2FIL
100
37
25µ
H deflection pulse input for H AFC.
Input an about 5Vp-p pulse via a capacitor. Set
the pulse width to 10 to 12µs. This pin is also
used as the hold-down signal input for the HD
output, and if this pin is 1 [V] or less for a 7V
cycle or longer, the hold-down function operates
and the HD output goes to high (OFF).
In addition, the RGB outputs are all blanked and
the status is returned to the I2C bus.
Filter for H AFC.
Connect to GND via a capacitor. The H phase
can also be controlled from this pin by leading
current in and out of this capacitor.
As the pin voltage rises, the picture shifts to the
left; as the pin voltage drops, the picture shifts to
the right.
JVCC
38
AFCFIL
1.2k
46k
CR connection for the AFC lag-lead filter.
38
50µ
50µ
JVCC
10k
39
CERA
39
Connect the ×32fH VCO ceramic oscillator.
400µ
50µ
40
GND for the deflection block.
JGND
–7–
CXA2095S
Pin
No.
Symbol
Equivalent circuit
Description
JVCC
41
IREF
Internal reference current setting.
Connect to GND via a 15kΩ resistor.
20k
147
41
JVCC
42
VSFIL
Filter for V sync separation.
Connect to GND via a capacitor.
42
1k
JVCC
43
VSIN
147
Sync signal input for V sync separation.
Input a 2Vp-p Y signal.
43
20µ
JVCC
44
HSIN
147
Sync signal input for H sync separation.
Input a 2Vp-p Y signal.
44
10µ
SVCC
45
VM
Y signal differential waveform output for VM
(Velocity Modulation). (7.1VDC, 2.0Vp-p) The
signal delayed for 250ns from YIN is output.
The delay time from YIN and the differential
coefficient of the output signal vary according to
sharpness f0 control.
45
400µ
1k
46
BGP
Burst gate pulse output.
This pulse is a 0 to 3V positive polarity pulse.
While this pulse is gated near V-Sync for the
CXA2025S, it is constantly output for the
CXA2095S.
46
15k
1k
–8–
CXA2095S
Pin
No.
Symbol
Equivalent circuit
Description
SVCC
47
147
FSCOUT
Sub carrier output.
Output level: 5.9VDC, 0.5Vp-p
47
300µ
48
This pin is not connected.
Connect to GND normally to prevent interference
to others.
NC
–9–
– 10 –
∆fHR
VBGPh
VSpp
VSdc
Horizontal sync pull-in
range
HD output pulse width
BGP output pulse width
VDRIVE output
amplitude
VDRIVE output center
potential
4
5
6
7
8
HDw
fHFR
Horizontal free-running
frequency
Item
3
No.
Symbol
JICC
Sync block current
consumption
2
Sync deflection block items
SICC
Symbol
Signal block current
consumption
Item
1
No.
SYNC IN: composite sync
SYNC IN: composite sync
SYNC IN: composite sync
AFC MODE = 0H
29,
30
29,
30
46
35
—
35
Measurement pin
34
JVCC = 9.0V,
Bus data = center
Measurement conditions
6
Measurement pin
SVCC = 9.0V,
Bus data = center
Measurement conditions
24.5
Measure the pulse width for the section where the
HDRIVE output is high.
43: VSIN in
VDRIVE+
8.97ms VSdc
VSpp
Measure the VDRIVE output Vp-p.
2.9
0.8
3.1
–400
Measure the pulse width for the section where the BGP
output is high.
Typ.
45
65
Typ.
3.0
0.95
4.0
25.5
—
mA
mA
3.15
1.1
4.9
26.5
400
V
V
µs
µs
Hz
kHz
Max. Unit
60
90
Max. Unit
15.55 15.734 15.9
Min.
25
40
Min.
Confirm that I2C status register HLOCK is 1
(the pull-in range when fH is shifted from 15.734kHz).
HDRIVE output frequency
Measurement contents
Measure the pin inflow current.
Measure the pin inflow current.
Measurement contents
Setting conditions
• Ta = 25°C, SVCC = JVCC = 9V, SGND = JGND = 0V
• Measures the following after setting the I2C bus register as shown in “I2C bus register initial settings”.
Electrical Characteristics
CXA2095S
– 11 –
Lin
R, G and B output
linearity
C-TRAP attenuation
12
13
C-Trap
VRout1
R, G and B output
amplitude
Item
11
No.
Symbol
VEWdc
EWDRIVE output center
potential
10
Signal block items
VEWpp
Symbol
EWDRIVE output
amplitude
Item
9
No.
C-TRAP = 0/1
CTRAP-ADJ = 7H
100 IRE
50 IRE
1.4Vp-p/100 IRE
YIN:
fsc, 50 IRE
YIN:
YIN:
Measurement conditions
SYNC IN: composite sync
Measurement conditions
20
20,
22,
24
V1
Lin =
V1
× 100
V2 × 2
f = 3.58MHz
Input fsc to YIN.
Ratio of the fsc component of the Rout amplitude when
CTRAP=1 against the Rout amplitude when CTRAP=0.
V2
Output amplitude when a video signal with an amplitude
of 1.4Vp-p/100 IRE is input
20,
22,
24
8.97ms
Measurement contents
43: VSIN in
VEWpp
Measure the EWDRIVE output Vp-p.
Measurement contents
Measurement pin
31
31
Measurement pin
—
95
2.1
Min.
3.7
0.5
Min.
–37.5
100
2.4
Typ.
4.0
0.65
Typ.
V
V
—
105
2.7
dB
%
V
Max. Unit
4.2
0.8
Max. Unit
CXA2095S
– 12 –
24
20,
22,
24
∆GdcolB
∆GYM
Dynamic color operation
B output
YM gain
20
21
D-COL = 0/1
SUBCONT = F
YIN: 100 IRE
∆GdcolR
Dynamic color operation
R output
19
20
∆fAPC
APC pull-in range
18
—
—
YIN = GND
CIN: burst only
KP
Killer point
17
—
HUE = 1F, SUB-HUE = 7
φoffset
Hue center offset
16
24
Color gain
15
Vcol
Vvm
YIN: GND
CIN: burst
+180°, 500mVp-p
COLOR = 1F
Measurement pin
45
Measurement conditions
YIN: 3MHz, 50 IRE
VM = 1
Symbol
VM output
Item
14
No.
CIN
Vpp
0° 500mVpp
50 IRE
Vpp (DCOL = 1)
× 100
Vpp (DCOL = 0)
∆GdcolB =
Output amplitude ratio of the R, G and BOUT when YM
is high and low
Vpp (DCOL = 1)
× 100
Vpp (DCOL = 0)
Vpp
∆GdcolR =
ROUT, BOUT
Confirm that the burst frequency is pulled in at 3.58MHz
±400Hz.
Confirm that status register KILLER is 1 when the burst
level is –31dB assuming burst 570mVp-p to be 0dB.
BOUT
Vvm
VM
180°
f = 3MHz
YIN
Measurement contents
–7.1
104
94
–400
—
–8.5
0.75
1.5
Min.
–6.1
106
96
—
–31
0
0.98
2.2
Typ.
–5.1
108
98
400
—
8.5
1.2
2.4
dB
%
%
Hz
dB
deg
V
V
Max. Unit
CXA2095S
IK level G
IK level B
29
30
– 13 –
VIKB
VIKG
GCUTOFF = 0
BCUTOFF = 0
25
25
25
24
YS: 1V
RGBIN: 0.7V
B output amplitude during
VLBout
linear B input
27
SYNC IN: composite sync
22
YS: 1V
RGBIN: 0.7V
G output amplitude during
VLGout
linear G input
26
VIKR
20
YS: 1V
RGBIN: 0.7V
R output amplitude during
VLRout
linear R input
25
IK level R
24
YUVSW: 2V
EBYIN: 0.4V
B output amplitude during
VBout1
external B-Y input
24
28
20
YUVSW: 2V
ERYIN: 0.4V
R output amplitude during
VRout3
external R-Y input
23
Measurement pin
20
Measurement conditions
YUVSW: 2V
EYIN: 0.7V
Symbol
R output amplitude during
VRout2
external Y input
Item
22
No.
IKIN
R, G, B out
EYIN
ERYIN
EBYIN
RGBIN
VIKR VIKG VIKG
Vout
Vin
Measurement contents
VBout = Vout
VGout = Vout
VRout = Vout
VBout1 = Vout
VRout3 = Vout
VRout2 = Vout
0.42
0.42
0.8
1.9
1.9
1.9
1.34
1.25
2.05
Min.
0.60
0.60
0.98
2.23
2.23
2.23
1.64
1.7
2.4
Typ.
0.78
0.78
1.16
2.55
2.55
2.55
1.94
2.15
2.75
V
V
V
V
V
V
V
V
V
Max. Unit
CXA2095S
CXA2095S
Electrical Characteristics Measurement Conditions “I2C bus register initial settings”
PICTURE
VM
DC-TRAN
COLOR
AXIS
D-COL
SHARPNESS
SHP-F0
CTRAP-ADJ
SUB-HUE
GAMMA
AGING1
B-DRIVE
B-CUTOFF
CD-MODE2
GON
PICON
FHHI
AKBOFF
V-COMP
AFC-MODE
V-LIN
REF-POSI
VBLKW
PIN-PHASE
LO-CPIN
AFC-ANGLE
ZOOMSW
V-SCROLL
UP-VLIN
LEFT-BLK
= 3F Hex
=0
=0
= 1F Hex
=0
=0
= 7 Hex
=2
= 7 Hex
= 7 Hex
=0
=0
= 2A Hex
= 0 Hex
=0
=1
=1
=0
=0
=0
=1
= 7 Hex
=3
=0
= 7 Hex
= 0 Hex
= 7 Hex
=0
= 1F Hex
= 0 Hex
= 7 Hex
C-TRAP
HUE
D-PIC
TOT
BRIGHT
ABL
PRE-OVER
SUB-CONT
SUB-COLOR
SUB-BRIGHT
G-DRIVE
AGING2
G-CUTOFF
EY-SW
RON
BON
VOFF
CD-MODE
V-SIZE
V-POSITION
S-CORR
H-SIZE
PIN-COMP
H-POSITION
UP-CPIN
AFC-BOW
V-ASPECT
HBLKSW
JMPSW
LO-VLIN
RIGHT-BLK
– 14 –
=0
= 1F Hex
=0
=0
= 1F Hex
=0
=3
= 7 Hex
= 7 Hex
= 1F Hex
= 2A Hex
=0
= 0 Hex
=0
=1
=1
=0
=0
= 1F Hex
= 1F Hex
= 0 Hex
= 1F Hex
= 1F Hex
= 7 Hex
= 0 Hex
= 7 Hex
= 0 Hex
=0
=0
= 0 Hex
= 7 Hex
1.5k
3.579545
MHz
15p
503k
2.7k
100
XTAL
1
2
YIN
4
5
220
16
17
Analog
RGB input
0.1µ
100
20
19
18
1k
10µ
26
25
RGB output
100
24
0.1µ
23
0.47µ
IK input
ABL/High voltage fluctuation
compensation signal input
100
22
0.1µ
21
GSH
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 patent and other right due to same.
YM/YS
signal input
220
YS
15
220
14
13
12
0.1µ 0.1µ 0.1µ
11
ERYIN
PINP Y/color difference
signal input
220
I2C bus
input/output
220
10
9
8
C signal input
0.47µ
Y signal input
3
7
NC
0.47µ
6
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
10µ
100
43
100
10k
44
100
V parabola
wave output
FSCOUT
15k 390
10k
HD output
V sawtooth
wave output
V timing pulse output
V protect signal input
45
470p
BGP
BLHOLD
15k
CIN
0.01µ
APCFIL
VM
46
4.7µ
HSIN
47
0.47µ
VSIN
SVCC
48
330k
VSFIL
47µ
SCL
IREF
SDA
3.5k
1µ
100
8.2k
JGND
YUV SW
100p
220
1µ
CERA
0.01µ
AFCFIL
EYIN
1k
0.0027µ
EBYIN
L2FIL
0.1µ
AFCPIN/HOFF
SGND
HDRIVE
YM
JVCC
0.01µ
Hold-down input
0.1µ
SAWOSC
GOUT
+9V
0.0047µ
HP input
0.01µ
fsc
BGP
output output
0.01µ
Signal output
for VM
47µ
VAGCSH
RIN
EWDRIVE
0.01µ
ABLIN/VCOMP
0.1µ
VDRIVE+
/VPROT
GIN
VDRIVE–
/VPROT
BIN
VTIM
RSH
ABLFIL
ROUT
– 15 –
BSH
IKIN
BOUT
Application Circuit
CXA2095S
330p
SYNCIN
1.5k
3.579545
MHz
15p
10k
48
1
47
2
46
3
45
4
YIN
44
5
1µ
100
CIN
40
9V
I2CBUS
220
220
9
8
41
7
42
6
43
503kHz
39
width 10µs
4.7µ
470p
38
10k
37
CXA2095S
11
12
36
HOFF
34
YM
220
220
YS
15
14
35
2.7k
9V
HDRIVE
14
33
16
32
17
10k
13
4538
4
100
RGBIN
ROUT
100
20
19
18
0.1µ
28
100
22
GOUT
0.1µ
21
27
10µ
100
29
100
30
31
100
9
25
ABL
26
8
7
10
6
11
5
12
5.1k
5.1k
VPROT
VDRIVE–
VTIM
E/W
VDRIVE+
10k
10k
3
2
15
1
16
2000p
13
220 0.1µ 0.1µ 0.1µ
10
15k 390
VSIN
SVCC
220
VSFIL
SCL
1k
HSIN
AFCPIN
0.47µ
IREF
SDA
FSCOUT BGP VM
0.0047µ
0.47µ
330k
delay 12µs
JGND
0.01µ
47µ
SGND
9V
NC
XTAL
FSCOUT
APCFIL
0.47µ
VM
YIN
BGP
BLHOLD
15k
HDRIVE
YM
2000p
0.01µ
HDRIVE
YUVSW
CIN
0.01µ
8.2k
EYIN
YUV SW
47µ
CERA
EYIN
AFCPIN/HOFF
JVCC
YS
1µ
AFCFIL
ERYIN
ERYIN
EWDRIVE
BIN
0.1µ
L2FIL
EBYIN
EBYIN
RSH
0.01µ
VDD
1T1
SAWOSC
RIN
2CD
1A
VDRIVE+
/VPROT
47µ
0.01µ
2A
1B
ROUT
0.1µ
2T1
1T2
VAGCSH
GIN
2B
1Q
VTIM
VDRIVE–
/VPROT
GSH
0.1µ
2T2
1CD
0.01µ
2Q
1Q
ABLFIL
GOUT
0.1µ
2Q
VSS
ABLIN/VCOMP
23
BOUT
10k
20k
P1
51k
D1 D2 D3
IKIN
100
1µ
0.001µ
100
24
0.1µ
BSH
IKIN
– 16 –
BOUT
9V
9V
CXA2095S
Electrical Characteristics Measurement Circuit
Signal sources
are all GND unless otherwise specified in the Measurement conditions column of Electrical
Characteristics.
ABL
is 9V unless otherwise specified.
CXA2095S
Definition of I2C Bus Registers
Slave Addresses
88H: Slave receiver
89H: Slave transmitter
Control Register
Sub Address
BIT7
BIT6
BIT5
BIT4
BIT3
BIT2
BIT1
BIT0
∗ ∗ ∗ 0 0 0 0 0 00 H
PICTURE
C-TRAP
VM
∗ ∗ ∗ 0 0 0 0 1 01 H
HUE
DC-TRAN
D-PIC
∗ ∗ ∗ 0 0 0 1 0 02 H
COLOR
TOT
AXIS
∗ ∗ ∗ 0 0 0 1 1 03 H
BRIGHT
D-COL
ABL
∗ ∗ ∗ 0 0 1 0 0 04 H
SHARPNESS
∗ ∗ ∗ 0 0 1 0 1 05 H
SUB-CONT
CTRAP-ADJ
∗ ∗ ∗ 0 0 1 1 0 06 H
SUB-COLOR
SUB-HUE
PRE-OVER
SHP-F0
∗ ∗ ∗ 0 0 1 1 1 07 H
SUB-BRIGHT
∗ ∗ ∗ 0 1 0 0 0 08 H
G-DRIVE
AGING1
AGING2
∗ ∗ ∗ 0 1 0 0 1 09 H
B-DRIVE
EY-SW
CD-MODE2
∗ ∗ ∗ 0 1 0 1 0 0A H
∗ ∗ ∗ 0 1 0 1 1 0B H
GAMMA
B-CUTOFF
G-CUTOFF
RON
GON
BON
PICON
VOFF
FHHI
CD-MODE AKBOFF
∗ ∗ ∗ 0 1 1 0 0 0C H
V-SIZE
V-COMP
∗ ∗ ∗ 0 1 1 0 1 0D H
V-POSITION
AFC-MODE
∗ ∗ ∗ 0 1 1 1 0 0E H
V-LIN
S-CORR
∗ ∗ ∗ 0 1 1 1 1 0F H
H-SIZE
REF-POSI
∗ ∗ ∗ 1 0 0 0 0 10 H
PIN-COMP
VBLKW
∗ ∗ ∗ 1 0 0 0 1 11 H
H-POSITION
PIN-PHASE
∗ ∗ ∗ 1 0 0 1 0 12 H
UP-CPIN
LO-CPIN
∗ ∗ ∗ 1 0 0 1 1 13 H
AFC-BOW
AFC-ANGLE
∗ ∗ ∗ 1 0 1 0 0 14 H
V-ASPECT
∗ ∗ ∗ 1 0 1 0 1 15 H
V-SCROLL
ZOOMSW HBLKSW
JMPSW
∗ ∗ ∗ 1 0 1 1 0 16 H
UP-VLIN
LO-VLIN
∗ ∗ ∗ 1 0 1 1 1 17 H
LEFT-BLK
RIGHT-BLK
0
∗: Don't care
Status Register
BIT7
BIT6
BIT5
BIT4
BIT3
BIT2
BIT1
BIT0
HLOCK
IKR
VNG
HNG
KILLER
0
1
0
Note) EY-SW and CD-MODE2 have been added to the CXA2025S.
– 17 –
CXA2095S
Description of Registers
<Control Register>
Register name No. of bits
Function
PICTURE
(6)
: Picture gain control (RGB gain control)
0H = –15dB
3FH = 0dB
RGB output: 2.4Vp-p (I/O gain: +4.7dB, 1.4Vp-p input)
C-TRAP
(1)
: Y block chroma trap ON/OFF switch
0 = Trap OFF
1 = Trap ON (Y signal delay time adjusted when C-TRAP turned ON or OFF.)
VM
(1)
: Y signal differential output ON/OFF switch for VM
0: Output OFF
1: Output ON (2.0Vp-p)
HUE
(6)
: Hue control (Chroma demodulation axis control when SUB-HUE is 8H)
0H = +35°
Flesh color appears red.
1FH = 0°
3FH = –35°
Flesh color appears green.
DC-TRAN
(1)
: Y DC transmission ratio selector switch
0 = 100%
1 = 82%
DPIC
(1)
: Y black expansion ON/OFF switch
0 = OFF
1 = ON
Point of inflection: 30 IRE
COLOR
(6)
: Color gain control
0H = Color OFF (–40dB or less)
1FH = 0dB
B output: 1.1Vp-p (I/O gain: +5.7dB, 0.57Vp-p input)
3FH = +5.4dB
TOT
(1)
: Chroma TOT filter band selector switch
0 = TOT-TRAP OFF
1 = TOT-TRAP ON (TRAP f0 2.0MHz)
AXIS
(1)
: R-Y, G-Y axis selector switch
0 = Japan axis R-Y: 95° × 0.60, G-Y: 236° × 0.33
1 = US axis
R-Y: 105° × 0.78, G-Y: 236° × 0.33
(B-Y: 0° × 1)
– 18 –
CXA2095S
BRIGHT
(6)
: Bright level control (RGB DC bias control)
0H = –300mV
1FH = 0mV
–300mV from REF-P level
3FH = +300mV
D-COL
(1)
: Dynamic color ON/OFF switch
0 = Dynamic color OFF
1 = Dynamic color ON (R, Bch level control)
ABL
(1)
: ABL mode selector switch
0 = Picture ABL mode
1 = Picture/bright ABL mode
SHARPNESS
(4)
: Sharpness gain control (Y aperture correction gain control)
0H = –8dB
7H = 1dB
FH = +5.1dB
PRE-OVER
(2)
: Sharpness preshoot/overshoot ratio control
0H = 1:1
(PRE:OVER)
3H = 5:1
SHP-F0
(2)
: Sharpness f0 control (Delay line current control for aperture correction)
0H = 2.5MHz
3H = 4.0MHz
SUB-CONT
(4)
: Contrast gain control (Y gain control)
0H = –3.0dB
7H = 0dB
FH = +2.5dB
CTRAP-ADJ
(4)
: Chroma trap f0 adjustment (Y block chroma trap current control)
0H = +300kHz
7H = 0kHz
FH = –300kHz
fsc adjustable to –30dB or less (SHP-F0 min.); adjustment value: 3 to 4
SUB-COLOR
(4)
: Color gain control (ACC reference level control)
0H = –4.0dB
7H = 0dB
FH = +2.1dB
– 19 –
CXA2095S
SUB-HUE
(4)
: Hue control (Phase control for chroma demodulation axis when HUE = 1FH)
0H = +10°
7H = 0
FH = –10°
B-Y axis adjustable to 0°
SUB-BRIGHT
(6)
: Bright level control (RGB DC bias control)
0H = –300mV
1FH = 0mV
–300mV from REF-P level
3FH = +300mV
GAMMA
(2)
: Gamma control (RGB gamma correction amount control)
0H = Gamma OFF
3H = Gamma peak (40 IRE) +400mV
G-DRIVE
(6)
: Gch drive gain adjustment (Gch gain control)
0H = G/R
–3.8dB
2AH = G/R
0dB
3FH = G/R
+2.5dB
AGING1
(1)
: White output aging mode ON/OFF switch
(Has priority over RGBON and PICON control, set to OFF mode at poweron.)
0 = Aging mode OFF
1 = Aging mode ON
60 IRE flat signal output from Y block when input is
no signal
AGING2
(1)
: Black output aging mode ON/OFF switch
(Has priority over AGING1, set to OFF mode at power-on.)
0 = Aging mode OFF
1 = Aging mode ON
Black level output
B-DRIVE
(6)
: Bch drive gain adjustment (Bch gain control)
0H = B/R
–3.8dB
2AH = B/R
0dB
3FH = B/R
+2.5dB
EY-SW
(1)
: Internal Y signal fixed mode ON/OFF switch
0 = YUV SW (Pin 9) standard operation (EYIN, ERYIN and EBYIN input are
selected when Pin 9 is high.)
1 = EYIN (Pin 10) input only invalid (Internal Y, ERYIN and EBYIN input are
selected when Pin 9 is high.)
CD-MODE2
(1)
: Vertical sync pull-in speed switch
0 = Standard (equivalent to CXA2025S)
1 = High speed
– 20 –
CXA2095S
G-CUTOFF
(4)
: Gch cut-off adjustment (Gch reference pulse value control of IKIN pin input)
0H = 62%
7H = 100%
(G/R: Gch reference pulse amplitude when Rch reference
FH = 150%
pulse amplitude of IKIN pin input is assumed 100%)
B-CUTOFF
(4)
: Bch cut-off adjustment (Bch reference pulse value control of IKIN pin input)
0H = 62%
7H = 100%
(B/R: Bch reference pulse amplitude when Rch reference
FH = 150%
pulse amplitude of IKIN pin input is assumed 100%)
RON
(1)
: ON/OFF switch for Rch video output without a reference pulse
(Operates when PICON = 1, set to OFF mode at power-on.)
0 = Rch video output OFF (Blanked status, reference pulse only output)
1 = Rch video output ON
GON
(1)
: ON/OFF switch for Gch video output without a reference pulse
(Operates when PICON = 1, set to OFF mode at power-on.)
0 = Gch video output OFF (Blanked status, reference pulse only output)
1 = Gch video output ON
BON
(1)
: ON/OFF switch for Bch video output without a reference pulse
(Operates when PICON = 1, set to OFF mode at power-on.)
0 = Bch video output OFF (Blanked status, reference pulse only output)
1 = Bch video output ON
PICON
(1)
: ON/OFF switch for RGB output with a reference pulse (Set to OFF mode at
power-on.)
0 = RGB output OFF (All blanked status)
1 = RGB output ON
VOFF
(1)
: V sawtooth wave oscillation stop ON/OFF switch (Set to OFF mode at
power-on.)
0 = Oscillation stop OFF (VDRIVE– and VDRIVE+: normal output)
1 = Oscillation stop ON (VDRIVE– and VDRIVE+: DC output and DC value
vary according to V-POSITION.)
FHHI
(1)
: H oscillator frequency fixation ON/OFF switch (Set to ON mode at power-on.)
0 = H oscillator frequency fixation OFF AFC normal mode
1 = H oscillator frequency fixation ON
Oscillator frequency fixed to
maximum value (16.252kHz).
CD-MODE
(1)
: V countdown system mode selector switch
(Set to automatic selection mode during power-on.)
0 = Non-standard signal mode, standard signal mode and no signal mode
automatically selected
1 = Fixed to non-standard signal mode
(V oscillator frequency is 55Hz during no signal mode (free run).)
– 21 –
CXA2095S
AKBOFF
(1)
: AKB ON/OFF switch (Set to ON mode at power-on.)
0 = AKB ON
1 = AKB OFF IK clamp, IK S/H and reference pulse fixed to OFF.
R, G and B cut-off adjustment at AKB OFF performed by voltage
applied to Pins 19 (RSH), 21 (GSH) and 23 (BSH), respectively.
V-SIZE
(6)
: Vertical amplitude adjustment (V sawtooth wave gain control)
0H = –14%
Vertical picture size decreases.
1FH = 0%
Amplitude: 1.15Vp-p, center DC : 3V (when V-ASPECT = 1FH)
3FH = +14%
Vertical picture size increases.
V-COMP
(2)
: Compensation amount setting for vertical high voltage fluctuation (V sawtooth
wave gain control)
0H = 0%
V sawtooth wave amplitude compensation amount when 1V is
applied with respect to when 9V is applied of VCOMP (Pin 26)
3H = –5%
V sawtooth wave amplitude compensation amount when 1V is
applied with respect to when 9V is applied of VCOMP (Pin 26)
V-POSITION
(6)
: Vertical position adjustment (V sawtooth wave DC bias control)
0H = –0.09V
Picture position drops, VDRIVE+ output DC Down
1FH = 0V
Center DC: 3V
2FH = +0.09V Picture position rises, VDRIVE+ output DC Up
AFC MODE
(2)
: AFC loop gain control (PLL between Hsync and Hvco)
0H = H free run mode
1H = Small gain
2H = Medium gain
3H = Large gain
S-CORR
(4)
: Vertical S correction amount adjustment (V sawtooth wave secondary component
gain control)
0H = Secondary component amplitude by adding sawtooth wave is 0
FH = Secondary component amplitude by adding sawtooth wave is Maximum
V-LIN
(4)
: Vertical linearity adjustment (Gain control for V sawtooth wave secondary
component)
0H = 85% (Bottom/top of picture) Top of picture expanded; bottom of picture
compressed.
7H = 100% (Bottom/top of picture)
FH = 115% (Bottom/top of picture) Top of picture compressed; bottom of
picture expanded.
H-SIZE
(6)
: Horizontal amplitude adjustment (V parabola wave DC bias control)
0H = –0.5V
Horizontal picture size decreases, EWDRIVE output DC Down.
1FH = 0V
Amplitude: 0.58Vp-p, center DC: 4V (when V-ASPECT = 2FH)
3FH = +0.5V
Horizontal picture size increases, EWDRIVE output DC Up
REF-POSI
(2)
: Reference pulse timing setting
0H = (From VTIM rise) Rch: 22H, Gch: 23H, Bch: 24H
1H = (From VTIM rise) Rch: 20H, Gch: 21H, Bch: 22H
2H = (From VTIM rise) Rch: 18H, Gch: 19H, Bch: 20H
3H = (From VTIM rise) Rch: 16H, Gch: 17H, Bch: 18H
– 22 –
CXA2095S
PIN-COMP
(6)
: Horizontal pin distortion compensation amount adjustment (V parabola wave
gain control)
0H = 0.11Vp-p
Compensation amount minimum
1FH = 0.47Vp-p
Center DC: 4V (when V-ASPECT = 2FH)
3FH = 0.84Vp-p
Compensation amount maximum
VBLKW
(2)
: VBLK width control (Blanked width after reference pulse. Operates when
JMPSW = 1, blanked width after reference pulse is fixed to 1H when JMPSW = 0.)
0H = 12H from Bch REF-P
1H = 11H from Bch REF-P
2H = 10H from Bch REF-P
3H = 9H from Bch REF-P
H-POSITION
(4)
: Horizontal position adjustment (HAFC phase control)
0H = 1µs delay
Picture position shifts to right. Video delayed with
respect to HD.
7H = 0µs
FH = 1µs advance
Picture position shifts to left. Video advanced with
respect to HD.
PIN-PHASE
(4)
: Horizontal trapezoidal distortion compensation amount adjustment (V parabola
wave center timing control)
0H = 1.5ms advance
Horizontal size for top of picture increases.
Horizontal size for bottom of picture decreases.
7H = 0ms
Center timing is 8.9ms from VTIM.
FH = 1.5ms delay
Horizontal size for top of picture decreases.
Horizontal size for bottom of picture increases.
UP-CPIN
(4)
: Horizontal pin distortion compensation amount adjustment for top of picture (V
parabola wave gain control)
0H = +0.2V
Horizontal size for top of picture decreases.
7H = 0V
(0.7Vp-p, 4:3 mode)
FH = –0.2V
Horizontal size for top of picture increases.
LO-CPIN
(4)
: Horizontal pin distortion compensation amount adjustment for bottom of picture
(V parabola wave gain control)
0H = +0.2V
Horizontal size for bottom of picture decreases.
7H = 0V
(0.7Vp-p, 4:3 mode)
FH = –0.2V
Horizontal size for bottom of picture increases.
AFC-BOW
(4)
: Vertical line bow compensation amount adjustment (HAFC phase control
according to parabola wave)
0H = Top and bottom of picture delayed 500ns with respect to picture center
7H = 0ns
FH = Top and bottom of picture advanced 500ns with respect to picture center
AFC-ANGLE
(4)
: Vertical line slope compensation amount adjustment (HAFC phase control
according to sawtooth wave)
0H = Top of picture delayed 500ns, bottom of picture advanced 500ns with
respect to picture center
7H = 0ns
FH = Top of picture advanced 500ns, bottom of picture delayed 500ns with
respect to picture center
V-ASPECT
(6)
: Aspect ratio control
(V sawtooth wave gain control)
0H = 75%
16:9 CRT full
2FH = 100%
4:3 CRT full (amplitude: 1.23Vp-p)
3FH = 112%
– 23 –
CXA2095S
ZOOMSW
(1)
: Zoom mode ON/OFF switch for 16:9 CRT
(Top and bottom of V sawtooth wave squeezed and 25% of picture cut)
0 = Zoom OFF Sawtooth wave amplitude: 1.23Vp-p
1 = Zoom ON Sawtooth wave amplitude: 70%
HBLKSW
(1)
: HBLK width control ON/OFF switch during 4:3 software full display mode on a
16:9 CRT
0 = Control OFF HBLK pulse generated from HPIN.
1 = Control ON HBLK pulse generated as pulse generated from HPIN or as
pulse generated from HVCO and width adjusted.
Width adjustment is performed by the LEFT-BLK and RIGHTBLK registers.
V-SCROLL
(6)
: Vertical picture scroll control during zoom mode on a 16:9 CRT
(DC component added to sawtooth wave AGC output to control ZOOMSW cut
timing)
0H = –0.25V
Scrolled toward top of screen by 32H and top of picture
zoomed.
1FH = 0V
3FH = +0.25V Scrolled toward bottom of screen by 32H and bottom of picture
zoomed.
JUMPSW
(1)
: Reference pulse jump mode ON/OFF switch
(In addition to V-ASPECT control, sawtooth wave gain control performed for
100% of VBLK interval and 67% of picture interval)
0 = Jump mode OFF
1 = Jump mode ON
On a 4:3 CRT, jump mode expands the sawtooth wave amplitude to 112%
with V-ASPECT; on a 16:9 CRT, jump mode compresses the sawtooth
wave amplitude to 75% with V-ASPECT. The V blanking width is expanded
at both the top and bottom of the picture. Blanking for the bottom of the
picture starts 251H after VTIM, and blanking for the top of the picture can
be varied as the blanking width after the reference pulse by the VBLKW
register.
UP-VLIN
(4)
: Vertical linearity adjustment for top of picture
(Secondary component gain control for sawtooth wave added to sawtooth wave
AGC output)
0H = 100% (Bottom/top of picture)
FH = 115% (Bottom/top of picture) Top of picture compressed.
LO-VLIN
(4)
: Vertical linearity adjustment for bottom of picture
(Tertiary component gain control for sawtooth wave added to sawtooth wave
AGC output)
0H = 100% (Bottom/top of picture)
FH = 85% (Bottom/top of picture) Bottom of picture compressed.
LEFT-BLK
(4)
: HBLK width control for left side of picture when HBLKSW = 1
(Phase control for timing pulse generated from HVCO)
0H = +1.3µs
HBLK width maximum
7H = 0µs
Center HBLK: 13µs
FH = –1.3µs
HBLK width minimum
– 24 –
CXA2095S
RIGHT-BLK
(4)
<Status Register>
HLOCK
(1)
: HBLK width control for the right side of picture when HBLKSW = 1
(Phase control for timing pulse generated from HVCO)
0H = +1.3µs
HBLK width maximum
7H = 0µs
Center HBLK: 13µs
FH = –1.3µs
HBLK width minimum
: Lock status between Hsync and HVCO
0 = HVCO free run status
1 = Locked to Hsync
IKR
(1)
: AKB operation status
0 = REF-P return small and AKB loop unstable.
1 = REF-P return sufficient and AKB loop stable.
VNG
(1)
: Signal input status to VPROT pin
0 = No VPROT input
1 = VPROT input (In this case, RGB outputs are blanked.)
HNG
(1)
: Signal input status to HOFF pin
0 = No HOFF input
1 = HOFF input (In this case, RGB outputs are blanked.)
KILLER
(1)
: Color killer status
0 = Killer OFF status
1 = Killer ON status
Note) The following have been added to the CXA2025S.
EY-SW: Sub Add 09H, Bit 1
CD-MODE2: Sub Add 09H, Bit 0
– 25 –
CXA2095S
Description of Operation
1. Power-on sequence
The CXA2095S does not have an internal power-on sequence. Therefore, all IC operations are controlled by
the set microcomputer (I2C bus controller).
1) Power-on
The IC is reset and the RGB outputs are all blanked. Hdrive starts to oscillate, but oscillation is at the
maximum frequency (16kHz or more) and is not synchronized to the input signal. Output of vertical signal
VTIM starts, VDRIVE outputs V sawtooth wave. Bus registers which are set by power-on reset are as follows.
AGING1
= 0: All white output aging mode OFF
AGING2
= 0: All black output aging mode OFF
RON
= 0: Rch video blanking ON
GON
= 0: Gch video blanking ON
BON
= 0: Bch video blanking ON
PICON
= 0: RGB all blanking ON
VOFF
= 0: V sawtooth wave oscillation mode ∗ VOFF = 1 for the CXA2025S.
FHHI
= 1: H oscillator maximum frequency mode
CD-MODE = 0: Automatic selector mode of the countdown mode
AKBOFF = 0: AKB mode
2) Bus register data transfer
The register setting sequence differs according to the set sequence. Register settings for the following
sequence are shown as an example.
Set sequence
Power-on
↓
Degauss
↓
IC initial setting
↓
AKB operation start
↓
AKB loop stable
↓
Video output
CXA2095S register settings
Reset status in 1) above.
↓
Reset status in 1) above.
The CRT is degaussed in the completely darkened condition.
↓
The IC is set to the power-on initial settings. (See the following page.)
The HDRIVE oscillator frequency goes to the standard frequency (around
15.734kHz).
↓
PICON is set to 1 and a reference pulse is output from Rout, Gout and
Bout. Then, the IC waits for the cathode to warm up and the beam current
to start flowing.
↓
Status register IKR is monitored.
IKR = 0: No cathode current
IKR = 1: Cathode current
Note that the time until IKR returns to 1 differs according to the initial
status of the cathode.
↓
RON, GON and BON are set to 1 and the video signal is output from
Rout, Gout and Bout.
– 26 –
CXA2095S
3) Power-on initial settings
The initial settings listed here are reference values, and initial settings may be determined freely according to
the set usage conditions.
PICTURE
= 3F Hex
Max (User Cont.)
C-TRAP
=0
Chroma Trap OFF
VM
=1
VM out ON
HUE
= 1F Hex
Center (User Cont.)
DC-TRAN
=0
Y DC transmission ratio 100%
D-PIC
=1
Y black expansion ON
COLOR
= 1F Hex
Center (User Cont.)
TOT
=0
Chroma low frequency increased
AXIS
=0
R-Y, G-Y Japan axis
BRIGHT
= 1F Hex
Center (User Cont.)
D-COL
=1
Dynamic Color ON
ABL
=1
Picture/bright ABL mode
SHARPNESS = 7 Hex
Center (User Cont.)
PRE-OVER
=0
Sharpness pre/over ratio 2:1
SHP-F0
=1
Sharpness f0 3MHz
SUB-CONT
= 7 Hex
Center (Adjust)
CTRAP-ADJ = 7 Hex
Center (Adjust)
SUB-COLOR = 7 Hex
Center (Adjust)
SUB-HUE
= 7 Hex
Center (Adjust)
SUB-BRIGHT = 1F Hex
Center (Adjust)
GAMMA
=0
Gamma OFF
G-DRIVE
= 1F Hex
Center (Adjust)
AGING1
=0
Aging Mode OFF
AGING2
=0
Aging Mode OFF
B-DRIVE
= 1F Hex
Center (Adjust)
G-CUTOFF
= 7 Hex
Center (Adjust)
B-CUTOFF
= 7 Hex
Center (Adjust)
EY-SW
=0
Standard
CD-MODE2 = 0
Standard
RON
=0
Rch video output OFF
GON
=0
Gch video output OFF
BON
=0
Bch video output OFF
PICON
=0
RGB all blanked
VOFF
=0
Vdrive oscillation stopped
FHHI
=0
Horizontal oscillator frequency standard
CD-MODE
=0
V countdown auto mode
AKBOFF
=0
AKB ON
V-SIZE
= 1F Hex
Center (Adjust)
V-COMP
=3
Vdrive high voltage fluctuation compensation amount max
V-POSITION = 1F Hex
Center (Adjust)
AFC-MODE = 2
Center
S-CORR
= 7 Hex
Center (Adjust)
V-LIN
= 7 Hex
Center (Adjust)
H-SIZE
= 1F Hex
Center (Adjust)
REF-POSI
=0
PIN-COMP
= 1F Hex
Center (Adjust)
VBLKW
=0
– 27 –
CXA2095S
(Power-on initial settings cont.)
H-POSITION
PIN-PHASE
UP-CPIN
LO-CPIN
AFC-BOW
AFC-ANGLE
V-ASPECT
ZOOMSW
HBLKSW
V-SCROLL
JMPSW
UP-VLIN
LO-VLIN
LEFT-BLK
RIGHT-BLK
= 7 Hex
= 7 Hex
= 7 Hex
= 7 Hex
= 7 Hex
= 7 Hex
= 0 Hex
=1
=1
= 1F Hex
=0
= 7 Hex
= 7 Hex
= F Hex
= F Hex
Center (Adjust)
Center (Adjust)
Center (Adjust)
Center (Adjust)
Center (Adjust)
Center (Adjust)
16:9 CRT Full Mode
16:9 CRT
Hblk width adjust ON
Center (User)
16:9 CRT Full Mode
16:9 CRT Full Mode
16:9 CRT Full Mode
Hblk width min.
Hblk width min.
2. Various mode settings
The CXA2095S contains bus registers for deflection compensation which can be set for various wide modes.
Wide mode setting registers can be used separately from registers for normal picture distortion adjustment,
and once distortion adjustment has been performed in full mode, wide mode settings can be made simply by
changing the corresponding register data.
• VDRIVE signal picture distortion adjustment registers
V-SIZE, V-POSITION, S-CORR, V-LIN
• E/WDRIVE signal picture distortion adjustment registers
H-SIZE, PIN-COMP, PIN-PHASE, UP-CPIN, LO-CPIN
• Wide mode setting registers
V-ASPECT, ZOOMSW, HBLKSW, V-SCROLL, JMPSW, UP-VLIN, LO-VLIN, LEFT-BLK, RIGHT-BLK
Examples of various modes are listed below. These modes are described using 480 lines as the essential
number of display scanning lines. Wide mode setting register data is also listed, but settings may differ slightly
due to IC variation. The standard setting data differs for 16:9 CRTs and 4:3 CRTs.
Register
16:9 CRT
4:3 CRT
V-ASPECT
V-SCROLL
ZOOMSW
UP-VLIN
LO-VLIN
JMPSW
HBLKSW
LEFT-BLK
RIGHT-BLK
0H
1F H
1
0H
0H
0
0
7H
7H
2F H
1F H
0
0H
0H
0
0
7H
7H
– 28 –
CXA2095S
1) 16:9 CRT full mode
This mode reproduces the full 480 lines on a 16:9 CRT. 4:3 images are reproduced by stretching the picture to
the left and right. Normal images are compressed vertically, but 16:9 images can be reproduced in their
original 16:9 aspect ratio with a video source which compresses (squeezes) 16:9 images to 4:3 images.
The register settings are the 16:9 CRT standard values.
2) 16:9 CRT normal mode
In this mode, 4:3 images are reproduced without modification. A black border appears at the left and right of
the picture. In this mode, the H deflection size must be compressed by 25% compared to full mode. The
CXA2095S also has a register (H-SIZE) which controls the H size, but the control width is not sufficient for
25% compression. Therefore, external measures must be taken such as switching the H deflection coil. Full
mode should be used when performing memory processing and attaching a black border to the video signal.
H blanking of the image normally uses the flyback pulse input to AFCPIN (Pin 36). However, the blanking
width can be varied according to the control register setting when blanking is insufficient for the right and left
black borders.
The following three settings are added to the 16:9 CRT standard values for the register settings.
HBLKSW = 1
LEFT-BLK = Adjustment value
RIGHT-BLK = Adjustment value
The H angle of deflection also decreases, causing it to differ from the PIN compensation amount during H size
full status. Therefore, in addition to the wide mode registers, PIN-COMP must also be readjusted only for this
mode.
3) 16:9 CRT zoom mode
In this mode, 4:3 images are reproduced by enlarging the picture without other modification. The top and
bottom of normal 4:3 images are lost, but almost the entire picture can be reproduced for vista size video
software, etc. which already has black borders at the top and bottom. The enlargement ratio can be controlled
by the V-ASPECT register, and enlarging the picture by 33% compared to full mode allows zooming to be
performed for 4:3 images without distortion. In this case, the number of scanning lines is reduced to 360 lines
compared to 480 lines for full mode. The zooming position can be shifted vertically by the V-SCROLL register.
V blanking of the image normally begins from V sync and continues for 2H after the AKB reference pulse, and
the top and bottom parts are also blanked during this mode.
Adjust the following two registers with respect to the 16:9 CRT standard values for the register settings.
V-ASPECT = 2FH
V-SCROLL = 1FH or user control
4) 16:9 CRT subtitle-in mode
When Cinema Scope size images which have black borders at the top and bottom of the picture are merely
enlarged with the zoom mode in 3) above, subtitles present in the black borders may be lost. Therefore, this
mode is used to super-compress only the subtitle part and reproduce it on the display.
Add the LO-VLIN adjustment to the zoom mode settings for the register settings.
V-ASPECT = 2FH
V-SCROLL = 1FH or user control
LO-VLIN = Adjustment value
The LO-VLIN register causes only the linearity at the bottom of the picture to deteriorate. Therefore, UP-VLIN
should also be adjusted if the top and bottom of the picture are to be made symmetrical. Since the picture is
compressed vertically, the number of scanning lines exceeds 360 lines.
– 29 –
CXA2095S
5) 16:9 CRT V compression mode
This mode is used to reproduce two 4:3 video displays such as for PandP. The V size must be compressed to
67% in order to reproduce two displays on a 16:9 CRT without distortion using 480 scanning lines, and this can
be set by JMPSW. Compression is performed after the AKB reference pulse, so the reference pulse remains in
the overscan position. The V blanking width after the reference pulse becomes larger than normal and can be
varied by the VBLKW register. During this mode, the bottom V blanking width is also expanded to 10H wider
than normal so that the bottom of the picture is not overscanned.
16:9 CRT standard values are used with only the JMPSW setting changed for the register settings.
JMPSW = 1
6) 16:9 CRT Sony type wide zoom mode
This mode reproduces 4:3 video software naturally on wide displays by enlarging 4:3 images without other
modification and compressing the parts of the image which protrude from the picture into the top and bottom
parts of the picture. The display enlargement ratio is controlled by V-ASPECT, and the compression ratios at
the top and bottom of the picture are controlled by UP-VLIN and LO-VLIN.
Adjust the following three registers with respect to the 16:9 CRT standard values for the register settings.
V-ASPECT = Adjustment value
UP-VLIN = Adjustment value
LO-VLIN = Adjustment value
7) 4:3 CRT normal mode
This is the standard mode for 4:3 CRTs.
The register settings are the 4:3 CRT standard values.
8) 4:3 CRT V compression mode
This mode is used to reproduce M-N converter output consisting of 16:9 images expanded to a 4:3 aspect ratio
and other squeezed signals without distortion on a 4:3 CRT. The V size must be compressed to 75% in order
to reproduce 4:3 images in a 16:9 aspect ratio. Compressing the V size with the JMPSW register used in mode 5)
above, compresses the V size to 67%. Therefore, V-ASPECT is set to enlarge the V size by 8%. AKB
reference pulse handling and V blanking are the same as for mode 5) above.
4:3 CRT standard values are used with the V-ASPECT and JMPSW settings changed for the register settings.
V-ASPECT = 3FH
JMPSW = 1
– 30 –
CXA2095S
Mode Settings
Setting CRT SIZE SOFT SIZE
I2C BUS REGISTER
MODE NAME
1)-1
16:9
16:9
16:9 CRT full
V-ASPECT = 0h: V size 75%
1)-2
16:9
4:3
Wide full
V-ASPECT = 0h: V size 75%
16:9 CRT normal
V-ASPECT = 0h: V size 75%
HBLKSW = 1h: HBLK width adjustment ON
LEFT-BLK = Adjustable
RIGHT-BLK = Adjustable
PIN-COMP = Adjustable
(External support: H-DY H amplitude 75%)
16:9 CRT zoom
V-ASPECT = 2Fh: V size 100%
ZOOMSW = 1h: Zoom ON
V size limited at 75%
V-SCROLL = 0h: Zoom bottom of video image
1Fh: Zoom center of video image
3Fh: Zoom top of video image
Adjustable: Open to user
16:9 CRT with
subtitle area on
V-ASPECT = 2Fh: V size 100%
UP-VLIN
= Adjustable: Slightly compresses top of
video image
LO-VLIN
= Adjustable: Significantly compresses
bottom of video image
ZOOMSW
1h: V size limited at 75%
(V-SCROLL = Adjustable)
4:3
16:9 CRT
V compression
V-ASPECT = 0h: V size 75%
JMPSW
= 1h: Reference pulse skipping ON
V size compressed 67% after the reference pulse
(compressed to 50% total)
VBLKW
= Adjustable: VBLK width expanded at
top and bottom of video image
V-ASPECT = Adjustable: V size 90%
UP-VLIN
= Adjustable:
Compression of top and
LO-VLIN
= Adjustable:
bottom of video image
(S-CORR = Adjustable):
2)
3)
4)
5)
16:9
16:9
16:9
16:9
4:3
4:3
4:3
(16:9
+ subtitle
area)
6)
16:9
4:3
16:9 CRT wide
zoom
7)
4:3
4:3
4:3 CRT normal
V-ASPECT = 2Fh: V size 100%
4:3 CRT
V compression
V-ASPECT = 3Fh: V size 112%
JMPSW
= 1h: Reference pulse skipping ON
(compressed to 75% total)
VBLKW
= Adjustable: VBLK width expanded at
top and bottom of video image
8)
4:3
16:9
∗ The amount of picture distortion compensation in a vertical direction position of the CRT does not change in
response to the above modes; as a result, the initial values of each picture distortion register can be used as
it is.
– 31 –
CXA2095S
3. Signal processing
The CXA2095S is comprised of sync signal processing, H deflection signal processing, V deflection signal
processing, and Y/C/RGB signal processing blocks, all of which are controlled by the I2C bus.
1) Sync signal processing
The Y signals input to Pins 43 and 44 are sync separated by the horizontal and vertical sync separation
circuits. The resulting horizontal sync signal and the signal obtained by frequency dividing the 32 FH-VCO
output using the ceramic oscillator (frequency 503.5kHz) by 32 are phase-compared, the AFC loop is
constructed, and an H pulse synchronized with the H sync is generated inside the IC. Adjustment of the H
oscillator frequency is unnecessary. When the AFC is locked to the H sync, 1 is output to the status register
(HLOCK) and that can be used to detect the presence of the video signal.
The vertical sync signal is sent to the V countdown block where the most appropriate window processing is
performed to obtain V sync timing information which resets the counter. AKB and other V cycle timing are then
generated from this reset timing.
2) H deflection signal processing
The H pulse obtained through sync processing is phase-compared with the H deflection pulse input from Pin
36 to control the phase of the HDRIVE output, and so the horizontal position of the image projected on the
CRT is controled. In addition, the compensation signal generated from the V sawtooth wave is superimposed.
As a result, the vertical picture distortion is compensated.
The H deflection pulse is used to H blank the video signal. When the pulse input from Pin 36 has a narrow
width, the pulse generated by the IC can be added to the H deflection pulse and used as the H blanking pulse.
(HBLKSW)
Pin 36 is normally pulse input, but if the pin voltage drops to the GND level, HDRIVE output goes to high level
(DC) and 1 is output to the status register (HNG). To release this status, turn the power off and then on again.
3) V deflection signal processing
The V sawtooth wave is generated at the cycle of the reset pulse output from the countdown system. After
performing wide deflection processing for this sawtooth wave, picture distortion adjustment is performed by the
VDRIVE and E/WDRIVE function circuits and the signal is output as the VDRIVE and E/WDRIVE signals.
4) Y signal processing
The Y signal input to Pin 4 (specified input level: level at which a 100% white (including sync, 140 IRE) signal
with a gain of 6dB with respect to the video signal standard becomes a 2Vp-p signal) passes through the
subcontrast control, trap for eliminating the chroma signal, sharpness control, clamp and black expansion
circuits, and is then input to the switching circuit (YUV SW) for the external Y/color difference signal. The
differential waveform of the Y signal delayed for approximately 200ns from the Y input is output from Pin 45 as
the signal for VM.
The VM signal is not output in the following cases.
When EY-SW = 0 and YUV SW (Pin 9) or YS (Pin 15) is high
When EY-SW = 1 and YS (Pin 15) is high
The f0 of the built-in filter is automatically adjusted inside the IC, but the trap f0 may require fine adjustment by
the I2C bus (CTRAP-ADJ) if it is affected by variation. When inputting a signal which has been Y/C separated
by a comb filter, etc., the trap should be turned OFF.
– 32 –
CXA2095S
5) C signal processing
The chroma signal input to Pin 5 (specified input level: level at which a 40 IRE burst level signal with a gain of
6dB with respect to the video signal standard becomes a 570mVp-p signal) passes through the ACC, TOT
(secondary HPF), color control and demodulation circuits. The signal then becomes the R-Y and B-Y color
difference signal and is input to the YUV SW circuit. When the burst level goes to –31dB or less with respect to
the specified input level, the color killer operates and the color difference signal is not output.
The external Y, color difference signals input to Pins 10, 11 and 12 pass through the clamp and amplifier
circuits and are input to the YUV SW circuit. The YUV SW circuit is controlled by the YUV SW (Pin 9).
However, its operation differs depending on the data in the I2C bus register (EY-SW). In other words, the YUV
SW circuit output is as follows.
When EY-SW = 0: Internal Y/color difference signal when YUV SW is low,
external Y/color difference signal (Pins 9, 10 and 11) when YUV SW is high
When EY-SW = 1: Internal Y/color difference signal when YUV SW is low,
internal Y/external color difference signal when YUV SW is high
When external Y/color difference signal is selected , the picture quality can be adjusted in the same manner as
with the normal internal Y signal by setting EY-SW to 1 and then inputting the external Y signal to YIN (Pin 4).
However, in this case the delay time between the Y signal and color difference signals must be realigned.
The specified input level for the external Y signal is the level at which a normal video signal standard, 100 IRE,
100% white signal becomes a 0.7Vp-p signal. The specified input level for the external color difference signal
is the level at which a normal video signal standard, 40 IRE burst level demodulates a 258mVp-p chroma
signal at orthogonal coordinates to become a 0.8 times signal (R-Y is demodulated by the 90° axis to become
a 1.14 times signal, B-Y is demodulated by the 0° axis to become a 2.03 times signal).
The G-Y signal is generated as the base of Y, color difference signals at the axis adjustment circuit. The Y
signal is added to R-Y, G-Y, and B-Y respectively and these signals become R, G, and B signals. And they are
input to the RGB block.
6) RGB signal processing
The RGB signals obtained from the Y/C block pass through the half-tone switch circuit (YM SW), the switch
circuit for the external RGB signal (YS SW), the picture control, dynamic color, gamma compensation, clamp,
brightness control, drive adjustment, cut-off adjustment and auto cut-off circuits, and are output to Pins 20, 22
and 24.
The RGB signals input to Pins 16, 17 and 18 are the level at which a normal video signal standard, 100 IRE,
100% white signal becomes a 0.7Vp-p signal.
The voltage applied to Pin 26 (ABLIN) is compared with the internal reference voltage, integrated by the
capacitor which is connected to Pin 27, and performs picture control and brightness control. In order to adjust
the white balance (black balance), this IC has a drive control function which adjusts the gain between the RGB
outputs and a cut-off control function which adjusts the DC level between the RGB outputs. Both drive control
and cut-off control are adjusted by the I2C bus, with the Rch fixed and the G and Bch variable. An auto cut-off
function (AKB) which forms a loop between the IC and CRT and performs adjustment automatically has also
been added. This function can compensate for changes in the CRT with time. Auto cut-off operation is as
follows.
• R, G and B reference pulses for auto cut-off, shifted 1H each in the order mentioned, appear at the top of
the picture (actually, in the overscan portion). The reference pulse uses 1H in the V blanking interval, and is
output from each R, G and B output pin.
• The cathode current (IK) of each R, G and B output is converted to a voltage and input to Pin 25.
• The voltage input to Pin 25 is compared with the reference voltage in the IC, and the current generated by
the resulting error voltage charges the capacitors connected to Pins 19, 21 and 23 for the reference pulse
interval and is held during all other interval.
• The loop functions to change the DC level of the R, G and B outputs in accordance with the capacitor pin
voltage so that the Pin 25 voltage matches the reference voltage in the IC.
The Rch for the reference voltage in the IC is fixed and the G and Bch are cut-off controlled by the I2C bus.
During G/B-CUTOFF center status, the loop functions so that the Rch, Gch and Bch for the reference pulse
input to Pin 25 is all 1Vp-p.
The reference pulse timing can be varied by the I2C bus.
When AKB is not used, the IC can be set to manual cut-off adjustment mode with I2C bus settings. In this
case, the DC level of the R, G and B outputs can be varied by applying voltages independently to Pins 19, 21
and 23.
– 33 –
CXA2095S
4. Notes on operation
When designing the board pattern for TV set, interference from around the power supply and GND should be
considered as the RGB and deflection signals output from the CXA2095S are DC direct connected.
Do not separate the GND patterns for each pin; a solid earth is ideal. Locate the power supply side of the bypass capacitor which is inserted between the power supply and GND as near to the pin as possible. Also,
locate the XTAL oscillator, ceramic oscillator and IREF resistor as near to the pin as possible, and do not wire
signal lines near this pin.
Drive the Y, external Y/color difference and external RGB signals at a sufficiently low impedance, as these
signals are clamped when they are input using the capacitor connected to the input pin.
The built-in capacitor receives the chroma signal, so apply a DC bias of about VCC/2 externally and input the
chroma signal at a sufficiently low impedance.
– 34 –
CXA2095S
Curve Data
I2C bus data conforms to the “I2C bus register initial settings” of the Electrical Characteristics Measurement
Conditions (P. 14).
V-POSITION
3.6
3.4
3.4
3.2
3.2
V [V]
V [V]
V-SIZE
3.6
3.0
2.8
3.0
2.8
VSIZE = 0
VSIZE = 1F
VSIZE = 3F
2.6
V-POSITION = 0
V-POSITION = 1F
V-POSITION = 3F
2.6
2.4
2.4
0
5
10
15
20
0
5
Time [ms]
S-CORR
15
20
V-LIN
3.6
3.6
3.4
3.4
3.2
3.2
V [V]
V [V]
10
Time [ms]
3.0
3.0
2.8
2.8
SCORR = 0
SCORR = 7
SCORR = F
2.6
VLIN = 0
VLIN = 7
VLIN = F
2.6
2.4
2.4
0
5
10
15
20
0
5
Time [ms]
10
15
20
Time [ms]
V-ASPECT
V-SCROLL
3.8
3.8
3.6
3.6
3.4
3.4
V [V]
V [V]
3.2
3.0
3.2
3.0
2.8
2.8
2.6
VASPECT = 0
VASPECT = 1F
VASPECT = 3F
2.4
VSCROLL = 0
VSCROLL = 1F
VSCROLL = 3F
2.6
2.2
2.4
0
5
10
15
20
0
Time [ms]
5
10
Time [ms]
– 35 –
15
20
CXA2095S
LO-VLIN
3.6
3.4
3.4
3.2
3.2
V [V]
V [V]
UP-VLIN
3.6
3.0
2.8
3.0
2.8
DATA-0
DATA-7
DATA-F
2.6
LO-VLIN = 0
LO-VLIN = 7
LO-VLIN = F
2.6
2.4
2.4
0
5
10
15
20
0
5
Time [ms]
10
15
20
Time [ms]
PIN-COMP
PIN-PHASE
4.1
4.2
4.0
4.0
3.9
3.8
V [V]
V [V]
3.8
3.6
3.7
3.6
3.4
3.5
PIN-COMP = 0
PIN-COMP = 1F
PIN-COMP = 3F
3.2
PIN PHASE = 0
PIN PHASE = 7
PIN PHASE = F
3.4
3.0
3.3
0
5
10
15
20
0
5
Time [ms]
10
15
20
Time [ms]
LO-CPIN
UP-CPIN
4.1
4.1
4.0
4.0
3.9
3.9
V [V]
V [V]
3.8
3.8
3.7
3.7
3.6
3.6
3.5
LO-CPIN = 0
LO-CPIN = 7
LO-CPIN = F
3.5
UP-CPIN = 0
UP-CPIN = 7
UP-CPIN = F
3.4
3.4
3.3
0
5
10
15
20
0
Time [ms]
5
10
Time [ms]
– 36 –
15
20
CXA2095S
H-SIZE
H POSITION
4.6
3.0
4.4
2.5
4.2
2.0
Time [µs]
V [V]
4.0
3.8
3.6
1.5
SYNC
center
44 HSIN
1.0
t [µs]
3.4
36 AFCPIN
0.5
HSIZE = 0
HSIZE = 1F
HSIZE = 3F
3.2
6µ s
12µs
3.0
0
0
5
10
15
20
0
2
4
6
10
8
12
14
16
12
14
16
DATA
Time [ms]
CTRAP
SHARPNESS
5
10
0
5
–5
0
Gain [dB]
Gain [dB]
–10
–15
–5
–20
–10
–25
SHARPNESS = 0
SHARPNESS = 7
SHARPNESS = F
–15
–30
CTRAP = 0
CTRAP = 1
–35
–20
0
1
2
3
4
5
6
7
0
2
4
Frequency [MHz]
6
10
8
Frequency [MHz]
PICTURE
COLOR
5
10
5
0
Gain [dB]
Gain [dB]
0
–5
–5
–10
–10
∗ COLOR OFF when DATA = 0
(–40dB or less)
–15
–15
–20
0
10
20
30
40
50
60
70
0
DATA
10
20
30
40
DATA
– 37 –
50
60
70
CXA2095S
SUB CONT
3
2
2
1
1
Gain [dB]
Gain [dB]
SUB COLOR
3
0
–1
–2
–3
–3
2
4
6
8
10
12
14
16
DATA
B-DRIVE, G-DRIVE
3
2
1
0
–1
–2
–3
–4
0
10
20
30
40
50
60
70
DATA
Potential difference between Rch reference pulse level and black level [Vp-p]
–4
0
Gain [dB]
–1
–2
–4
0
2
4
6
10
8
12
14
16
DATA
BRIGHT
0.25
0
–0.5
SUB-BRIGHT = 3F
SUB-BRIGHT = 1F
SUB-BRIGHT = 0
–1.0
0
07
0F
17
1F
27
2F
37
3F
DATA (Hex)
SUB-BRIGHT
GAMMA
0
5.0
–0.1
4.5
4.0
–0.2
Rch output [V]
Potential difference between Rch reference pulse level and black level [Vp-p]
0
–0.3
–0.4
–0.5
3.5
3.0
2.5
2.0
–0.6
1.5
0
07
0F
17
1F
27
2F
37
3F
GAMMA 0
GAMMA 1
GAMMA 2
GAMMA 3
0 10 20 30 40 50 60 70 80 90 100110 120
DATA (Hex)
YIN input amplitude [IRE]
– 38 –
CXA2095S
G, B – CUTOFF
IKIN reference pulse voltage [V]
4.0
3.5
Rch
Gch, Bch
IK clamp level
3.0
2.5
0
5
3
7
9
B
D
F
DATA (Hex)
R, G and B output reference pulse potential [V]
AKB open loop characteristics
4
3.5
3
2.5
2
1.5
1
0.5
0
0
1
2
3
4
5
6
7
8
Voltage applied to Rch, Gch and Bch sample-and-hold capacitance pins [V]
– 39 –
CXA2095S
Package Outline
Unit: mm
+ 0.1 5
0.0
0.25 –
48PIN SDIP (PLASTIC)
+ 0.4
43.2 – 0.1
25
15.24
+ 0.3
13.0 – 0.1
48
1
0° to 15°
24
0.5 ± 0.1
0.9 ± 0.15
+ 0.4
4.6 – 0.1
3.0 MIN
0.5 MIN
1.778
PACKAGE STRUCTURE
PACKAGE MATERIAL
EPOXY RESIN
SONY CODE
SDIP-48P-02
LEAD TREATMENT
SOLDER/PALLADIUM
PLATING
EIAJ CODE
SDIP048-P-0600
LEAD MATERIAL
COPPER / 42 ALLOY
PACKAGE WEIGHT
5.1g
JEDEC CODE
NOTE : PALLADIUM PLATING
This product uses S-PdPPF (Sony Spec.-Palladium Pre-Plated Lead Frame).
– 40 –