Sony 21T3 Schematic

21T3
SERVICE MANUAL
SPECIFICATIONS
data cable (1.8m)
Storable display modes: 15 (3 of which are preset)
Electrical data Video: analogue, positive, 0.7 Vp-p,
75 Ohm
Synchronisation: Separate Sync. TTL
Composite Sync. TLL/Sync. on Green
Horizontal frequency: 30 kHz .... 130 kHz
Refresh rate: 50 kHz .... 170 Hz
Maximum pixel rate: 300 MHz Power supply: switches automatically
Power consumption: < 135 W (ON, Normal mode) (see power management): < 3 W (OFF mode)
Environmental conditions Environment class 3K2, IEC 721
Rated range of operation: 15 °C .... 35 °C
Humidity: 20 % .... 85 %
Limit range of operation: 5 °C .... 40 °C
Humidity: 20 % .... 85 %
Condensation must be avoided.
AEP Model
Chassis No. SCC-L33M-A
CR1
(multi-scanning)
100 V .... 240 V, 50 Hz - 60 Hz
CHASSIS
COLOR MONITOR
1.5 k
0.15 µF
AC Voltmeter (0.75 V)
To Exposed Metal Parts on Set
Earth Ground
SAFETY CHECK-OUT
After correcting the original service problem, perform the following safety checks before releasing the set to the customer:
1. Check the area of your repair for unsoldered or poorly-soldered connections. Check the entire board surface for solder splashes and bridges.
2. Check the interboard wiring to ensure that no wires are “pinched” or contact high-wattage resistors.
3. Check that all control knobs, shields, covers, ground straps, and mounting hardware have been replaced. Be absolutely certain that you have replaced all the insulators.
4. Look for unauthorized replacement parts, particularly transistors, that were installed during a previous repair. Point them out to the customer and recommend their replacement.
5. Look for parts which, though functioning, show obvious signs of deterioration. Point them out to the customer and recommend their replacement.
6. Check the line cords for cracks and abrasion. Recommend the replacement of any such line cord to the customer.
7. Check the B+ and HV to see if they are specified values. Make sure your instruments are accurate; be suspicious of your HV meter if sets always have low HV.
8. Check the antenna terminals, metal trim, “metallized” knobs, screws, and all other exposed metal parts for AC Leakage. Check leakage as described below.
LEAKAGE TEST
The AC leakage from any exposed metal part to earth ground and from all exposed metal parts to any exposed metal part having a return to chassis, must not exceed 0.5 mA (500 microamperes). Leakage current can be measured by any one of three methods.
1. A commercial leakage tester, such as the Simpson 229 or RCA WT­540A. Follow the manufacturers instructions to use these instruments.
2. A battery-operated AC milliammeter. The Data Precision 245 digital multimeter is suitable for this job.
3. Measuring the voltage drop across a resistor by means of a VOM or battery-operated AC voltmeter. The limit indication is 0.75 V, so analog meters must have an accurate low-voltage scale. The Simpson 250 and Sanwa SH-63Trd are examples of a passive VOMs that are suitable. Nearly all battery operated digital multimeters that have a 2 V AC range are suitable. (See Fig. A)
Fig. A. Using an AC voltmeter to check AC leakage.
21T3 (E) 2
POWER SAVING FUNCTION
If your computer is equipped with power management, the monitor can support this func­tion fully . Here the monitor does not distinguish between the individual energy-saving modes of the computer (standby mode, suspend mode and OFF mode), as it is capable of immedi­ately switching into the mode with the highest energy-saving effect.
Stage ON Energy-saving mode
Power indicator glows green glows orange
Function Monitor Monitor
operating is dark
normally
Power consumption normal 135 W reduced to < 3 W
If your PC detects inactivity (no input) it sends an appropriate signal to the monitor to reduce the power consumption (energy-saving mode). The power indicator of the monitor changes colour to indicate the status change.
Once an input is mode at the PC the screen contents are redrawn and full power is restored.
For detailed information on how energy-sa ving mode operates refer to the Operating Manual or Technical Manual of your PC.
When the monitor is switched to the energy-saving mode by the po wer management system a power consumption of up to 3 W is maintained to feed the circuit for redra wing the screen contents.
T o completely switch of f the po wer consumption, switch off the monitor or the system unit.
21T3 (E) 4
DIAGNOSIS
Failure
+B failure
Horizontal / Vertical Deflection failure, Thermal protector
ABL protector
HV failure
Aging / Self Test
Out of scan range
Aging Mode (Video Aging) : During Power Save, press MENU button for longer than 2 second. Self Test (OSD Color Bar) : During Power Save, push button for longer than 2 second.
Amber Off
(0.5 sec) (0.5 sec) Amber Off
(1.5 sec) (0.5 sec)
Amber Off
(0.5 sec) (1.5 sec)
Amber Off Amber Off
(0.25 sec) (0.25 sec) (0.25 sec) (1.25 sec)
Amber Off Green Off
(0.5 sec) (0.5 sec) (0.5 sec) (0.5 sec) Green (OSD indication)
+
Power LED
21T3 (E) 5
TIMING SPECIFICATION
MODE AT PRODUCTION RESOLUTION CLOCK — HORIZONTAL — H-FREQ
H. TOTAL H. BLK H. FP H. SYNC H. BP H. ACTIV — VERTICAL — V. FREQ (Hz)
V. TOTAL V. BLK V. FP V. SYNC V. BP V. ACTIV — SYNC — INT(G) EXT (H/V) /POLARITY EXT (CS) /POLARITY INT/NON INT
MODE 1 MODE 2 MODE 3
640 X 480 1600 X 1200
25.175 MHz 229.500 MHz
31.469 kHz 106.250 kHz usec usec
31.778 9.412
6.356 2.440
0.636 0.279
3.813 0.837
1.907 1.325
25.422 6.972
59.900 Hz 85.000 Hz lines lines
525 1250
45 50 10 1
23
33 46
480 1200
NO NO
YES N/N YES P/P
NO NO
NON INT NON INT
1280 X 1024
157.500 MHz
91.146 kHz usec
10.971
2.844
0.406
1.016
1.422
8.127
85.024 Hz lines 1072
1024
NO
YES P/P
NO
NON INT
48
1 3
44
2001.7.4 VER.
21T3 (E) 6
TABLE OF CONTENTS
Section Title Page Section Title Page
1. DISASSEMBLY
1-1. Cabinet Removal ................................................ 1-1
1-2. A1 Board (C BLOCK) Removal ........................ 1-2
1-3. A1 Board Removal ............................................. 1-3
1-4. Bezel Assembly, H3 Board Removal ................. 1-4
1-5. D Board Removal ............................................... 1-5
1-6. Service Position................................................... 1-6
1-7. Picture Tube Removal......................................... 1-7
1-8. Harness Location ................................................ 1-9
2. SAFETY RELATED ADJUSTMENT ............... 2-1
3. ADJUSTMENTS ...................................................... 3-1
4. DIAGRAMS
4-1. Block Diagrams................................................... 4-1
4-2. Frame Schematic Diagram .................................. 4-4
4-4. Schematic Diagrams and Printed Wiring
Boards ................................................................. 4-6
(1) Schematic Diagram of A1 Board ....................... 4-8
(2) Schematic Diagrams of D (a, b, c) Board .. 4-10
(3) Schematic Diagram of DA Board ...................... 4-14
(4) Schematic Diagram of H3 Board ....................... 4-16
(5) Schematic Diagram of L2 Board ........................ 4-18
(6) Schematic Diagram of N Board .......................... 4-20
4-5. Semiconductors .................................................. 4-22
5. EXPLODED VIEWS .............................................. 5-1
5-1. Chassis ............................................................... 5-2
5-2. Picture Tube ...................................................... 5-3
5-3. Packing Materials................................................ 5-4
6. ELECTRICAL PARTS LIST ............................... 6-1
4-3. Circuit Boards Location ...................................... 4-5
21T3 (E) 7
1-1. CABINET REMOVAL
1
Two screws (+BVTP 4 x 16)
6
Slide the EMI shield in the direction of arrow C and remove four claws.
7
EMI shield
4
Three screws (+BVTT 4 x 8)
5
Three screws (+BVTT 4 x 8)
2
Two claws
Bezel assembly
Bezel assembly
EMI shield
Cabinet
Cabinet
Push in the tip of a screwdriver about 10mm to unlock the claw.
B
A
C
3
Push the upper side of the cabinet in the direction of arrow A, disconnect claws, then remove the cabinet lifting it up in the direction of arrow B.
SECTION 1
DISASSEMBLY
21T3(E) 1-1
1-2. A1 BOARD (C BLOCK) REMOVAL
CN318
1
A1 board (C BLOCK)
GND
GND
CN315
21T3(E) 1-2
1-3. A1 BOARD REMOVAL
8
A1 board
3
Four screws (+BVTP 3 x 8)
7
Video case
4
Video shield
6
Screw (+BVTP 3 X 8)
5
Four screws (HEX)
CN315
1
Two screws (+BVTP 3 x 8)
2
Video block assembly
21T3(E) 1-3
1-4. BEZEL ASSEMBLY, H3 BOARD REMOVAL
Before removing the bezel assembly, secure
1
the picture tube by attaching two screws to the picture tube shield at the positions shown with an arrow (diagonal two places) to prevent the picture tube from falling. (Use the screws +BVTT 4 x 8 that fix EMI shield.)
Picture tube shield
3
Screw (+BVTP 4 x 16)
10
L1 blacket
2
Four tapping screws (5)
5
Bezel assembly
11
Magnetic MIU-221D sensor
7
Input button
CN1500
CN1401
CN1400
6
Three screws (+BVTP 3 x 10)
8
H3 board
9
Two claws
4
Screw (+BVTP 4 x 16)
21T3(E) 1-4
1-5. D BOARD REMOVAL
4
Two screws (+BVTP 3 x 10)
3
Video block assembly
1
A1 board (C block)
Connector (4P)
5
6
Five screws (+BVTP 3 x 10)
CN605
CN701
Rear plate assembly
CN1601
CN1600
CN1103
CN1003
CN501
CN315
GND
2
Two screws (+BVTP 3 x 8)
8
D board
7
Screw (+BVTP 3X10)
Connector (4P)
CN602
CN601
GND
21T3(E) 1-5
1-6. SERVICE POSITION
1
Remove the D board.
2
Remove the Video block assembly.
3
Install the Adaptor board (XT MOUNT) (A-1391-123-A).
4
Lay the Video block assembly.
Video block assembly
2
4
3
D board
1
5
Install the video block assembly.
Video block assembly
6
Put a box which is about 15cm in height under the D board to fix it. (Please disconnect the CN 701 first.)
D board
Box
21T3(E) 1-6
1-7. PICTURE TUBE REMOVAL
1
Anode cap (Refer to 1-8)
3
Neck assembly
CN2
GND
CN3
2
A1 board (C block)
4
Picture tube
CN2
CN1
21T3(E) 1-7
REMOVAL OF ANODE-CAP
NOTE: Short circuit the anode of the picture tube and the anode cap to the metal chassis, CRT shield or carbon painted on the CRT, after
removing the anode.
REMOVING PROCEDURES
b
a
1Turn up one side of the rubber cap in the
direction indicated by the arrow a.
2Using a thumb pull up the rubber cap
firmly in the direction indicated by the arrow b.
HOW TO HANDLE AN ANODE-CAP
1Dont scratch the surface of anode-caps with sharp shaped
material!
2Dont press the rubber hardly not to damage inside of anode-
caps! A material fitting called as shatter-hook terminal is built in the rubber.
3Dont turn the foot of rubber over hardly!
The shatter-hook terminal will stick out or damage the rubber.
c
Anode Button
3When one side of the rubber cap is
separated from the anode button, the anode-cap can be removed by turning up the rubber cap and pulling up it in the direction of the arrow c.
21T3(E) 1-8
1-8. HARNESS LOCATION
H3 board
CN1401
CN1500
CN1400
Magnetic sensor
Picture tube
D board
AC inlet (3P)
CN2
CN1
4P
CN3
CN1
5P
4P
L2 board
CN701
CN1103
CN602
CN601
CN315
CN1602
CN1600
CN1601
CN1003
CN604 CN1102
CN312 CN311
CN320
CN501
CN904
N board
A1 board
CN303
CN316
CN318
CN319
21T3(E) 1-9
SECTION 2
SAFETY RELATED ADJUSTMENT
When replacing or repairing the shown below table, the following operational checks must be performed as a safety precaution against X-rays emissions from the unit.
Part Replaced ([)
HV ADJ
RV901
Part Replaced (])
HV Regulator Circuit Check
D Board C925, IC901, R901,
R902, R905, R924, R925, R926, RV901, T901 (FBT)
Mounted D Board
HV Protector Circuit Check
D Board C920, C923, D911,
D912, R903, R917,
Part Replaced (])
Beam Current Protector Circuit Check
D Board C930, D917, R921,
R932, R933, R935, T901 (FBT)
Mounted D Board
N Board IC1001, RB1001
Mounted N Board
* Confirm one minute after turning on the power.
a) HV Regulator Circuit Check
1) Turn the RV901 slowly, and adjustment so that high
voltage is in the specified range. [Specification]: 27.00 ± 0.05 kV
2) Check that the voltage of D912 cathode on the D
board is 17.0 V or more.
R918, R919, R920, R923, T901 (FBT)
Mounted D Board
N Board IC1001, RB1001
Mounted N Board
b) HV Protector Circuit Check
1) Using external DC Power Supply, apply the voltage
shown below between cathode of D912 and GND, and check that the RASTER disappers. [Specification]: 19.95 + 0.00/– 0.05 V
21T3 (E) 2-1
c) Beam Current Protector Circuit Check
1) Connect constant current source to a section between T901 (FBT) qa pin and GND, and check that the RASTER disappers when the specified current flows to the qa pin. [Specification]: 2.12 + 0.00/– 0.01 mA
21T3 (E) 2-2
SECTION 3
ADJUSTMENTS
Note:Hand degauss must be used on stand-by or power-off condition.
This model has an automatic earth magnetism correction function by using an earth magnetism sensor and a LCC coil. When using a hand degauss while monitor (LCC coil) is being operated, it sometimes gets magnetized, and the system may not work properly as a result.
Landing Rough Adjustment
1. Display all white pattern (or black dot pattern).
2. Set contrast to 255.
3. Display green plain pattern.
4. Side back DY and roughly adjust green plain pattern to be centered on the useful screen with Purity Magnet.
5. Adjust DY tilt.
Note:Set ROTATION to 128 and LCC_NS to 128 when adjusting DY tilt.
6. LIghtly tighten the DY screw.
Landing Fine Adjustment
Note: (1) After adjust W/B (9300k), measure the average of IK with all
white video input, while CONTRAST is maximum and BRIGHTNESS is center. And adjustment shall be made so that the miss-landing become least after aging 2H with the IK 30% of measured value shown above.
(2) The magnetic field shall be BH = 0.
1. Put the monitor in helmholz coil.
2. Set as follows; LCC_SW = 0 (LCC Correction Current = 0) FUNCTION_SW bit1 = (Auto Degauss = On) CONTRAST = 255
3. Display green plain pattern.
4. Degauss the iron part of chassis with a hand degausser and degauss coil.
5. Degauss CRT face with a hand degausser again.
6. Input AC 230V to AC IN and turn the monitor off and on. Then auto­degauss works.
7. Reset FUNCTION_SW bit1 to 0 (auto-degauss = off)
8. Degauss CRT face with a hand degausser again.
9. Attach wobbling coil to the specified place on CRT neck.
10. Put on landing sensor to CRT face.
11. Set LCC_SW to 12.
12. With landing checker, adjust DY position, purity, DY center and landing of the 4 corners.
(3) When adjusting at other than BH = 0, calculate the shifted value
from BH = 0.
13. Read VX and VY value which are the read out of magnetic sensor, and write to "LCC_VX_REF" and "LCC_VY_REF".
21T3 (E) 3-1
14. Adjust landing by LCC_NS, LCC_LT, LCC_LB, LCC_RT, and LCC_RB. Adjustment of registers shall be limited within the following range. LCC_NS: 128 ± 15 LCC_LT, LCC_LB, LCC_RT, and LCC_RB: 128 ± 40
Set LCC_SW to 13, and Perform Service Save.
<How to place wedge> Green plain crosshatch pattern
cd
a
a and b should be equal. c and d should be equal.
b
Plaster RTV to both sides for the upper wedge.
Make sure that they settle inside DY.
<Specifications> Adjust so that the green is within the specification given right. 4 corner adjust target : within ± 1
The red and blue must be within the specification given right with respect to the green.
A difference between red and blue must be within the specification given right.
0 ± 30 ± 7.5 0 ± 3 0 ± 30 ± 7.5 0 ± 3 0 ± 30 ± 7.5 0 ± 3
± 6 ± 6 ± 6 ± 6 ± 6 ± 6 ± 6 ± 6 ± 6
10 10 10 10 7 10 10 10 10
(µm)
(µm)
(µm)
15. Tighten DY screw within specified torque, and auto-degauss.
Note: Torque 22 ± 2 kgcm (2.2 ± 0.2Nm)
16. Adjust the vertical angle of DY to make top and bottom pins equal (a = b). The horizontal angle shall not be changed (straight). Settle DY upright without leaning, and insert wedges firmly so that DY shall not move.
Plaster RTV to one side for other wedges.
17. Adjust top and bottom pins correction VR.
18. Adjust the horizontal trapezoid distortion by DY horizontal trapezoid correction VR.
19. Check landing at each corner and in case not in specification, adjust landing of 4 corners with "LCC_NS", "LCC_LT", "LCC_LB", "LCC_RT", and "LCC_RB". The limitations of registers are shown below. LCC_NS: 128 ± 15 LCC_LT, LCC_LB, LCC_RT, and LCC_RB: 128 ± 40
20. Remove the sensor and wobbling coil.
21. Switch signals to R, G, and B, and then check that the pure colors have good color purity.
22. Fix purity magnets with white paint.
21T3 (E) 3-2
Connect the communication cable of the computer to the connector located on the D board. Run the service software and then follow the instruction.
IBM AT Computer
as a Jig
1-690-391-211A-1500-819-A
D-sub (9 Pin [female])
*The parts above ( ) are necessary for DAS adjustment.
mini Din (8Pin)
1
2
Interface Unit
3
Convergence Rough Adjustment
(1) Display white crosshatch pattern. (2) Pile the convex parts of 6-pole magnet for convergence together. (3) Roughly adjust H.CONV and V.CONV with 4-pole magnet.
Purity
4-pole magnet 6-pole magnet 2-pole magnet
H.TRAP
4 Pin
3-702-691-01
3
Connector Attachment
To BUS CONNECTOR
4 Pin 4 Pin
TLV
XBVXCV
B
R
R
B
TLH
R
BBR
YBHYCH
R B
B R
R B
R B
XCV
TLH
TB-PIN
Convergence Specification
B
V
A
A B
0.20 mm
0.24 mm
21T3 (E) 3-3
White Balance Adjustment Specification
Focus adjustment
1. 9300 K
x = 0.283 ± 0.005 y = 0.298 ± 0.005
(All White)
2. 6500 K
x = 0.313 ± 0.005 y = 0.329 ± 0.005
(All White)
3. 5000 K
x = 0.346 ± 0.005 y = 0.359 ± 0.005
(All White)
Vertical and Horizontal Position and Size
Specification
A
b
Adjust the focus volume 1 and 2 for the optimum focus.
Focus 1
Focus 2
FBT
b
a
a 1.8 mm b 1.8 mm
MODE
B
a
A B
4 : 3
388 291
21T3 (E) 3-4
4-1. BLOCK DIAGRAMS
CN309
HD15
5
15
10
14
9
4
3
13
CN307
HD15
CN311
DDC SCL1 DDC SDA1 DDC GND1 DDC SCL2 DDC SDA2 DDC GND2 H BLK INPUT SW IIC SCL IIC SDA HS OUT VS OUT ECO SW
8
2
12
7
1
11
6
5
15
10
14
4
9
3
13
8
2
12
7
1
11
6
SW
Q004
10 11
9 7 8 6
SW
Q005
SW
Q002
SW
Q001
1 4
SCL
15
SDA
16
HS OUT
2
VS OUT
3
ECO SW
13
(VIDEO AMP, RGB OUT)
A1
A
TO D BOARD CN1102
INPUT2(HD15)
INPUT1(HD15)
SECTION 4
DIAGRAMS
5
SDA
6
SCL
7
VCLK
IC007
ROM
IC008
INPUT SELECT
2
5
SDA
6
SCL
7
VCLK
IC009
ROM
IC006
INVERTER
985 6
3 4 11 10
1 2 13 12
B1
4
G1
6
R1
7
V1
8
H1
10
B2
12
G2
14
R2
15
V2
16
H2
13
SW
18 19 21
R OUT
G OUT
B OUT
SOG
SYNC IN
H OUT
V OUT
25
28
31
23
22
G.SYNC
SCL
SDA
SCL SDA HS OUT VS OUT ECO SW
7
R IN
4
G IN
2
B IN
22
SCL
23
SDA
4
SCL
3
SDA
12
HS OUT
13
VS OUT
27
ECO SW
23
CS IN
24
VS IN
25
HS IN
RGB PRE-AMP
OSD R
15 14 13 12
18 20 19 21
2
H FLY
OSD R
IC001
OSD G
OSD G
OSD B
OSD B
IC003
OSD
OSD BLK
V_DET
101718
7
11
AV
OSD BLK
R OUT
G OUT
B OUT
COF R COF G COF B
BLK
10
BLK
CLAMP
CLP
26
28
30
22 23 24
RCI GCI BCI
XTAL IN
15 14 13
32 31 30
14
8
R IN
9
G IN
11
B IN
RIN GIN BIN
BUFFER
Q101, Q201, Q301
IC002
RGB AMP
IC004
CUT OFF AMP
R_IK
12 11 10
X001
24.5MHz
5
R OUT
3
G OUT
1
B OUT
3
ROUT
5
GOUT
7
BOUT
G_IK
B_IK
7V
2
24
IC005
INVERTER
IC011
HEATER REG Vcc OUT
VADJ
5 3 1 7
CN315
KR KG KB HEATER+
CN318
KR KG KB HEATER+
5 3
V901
PICTURE TUBE
1 7
FVFCHV
G2
CN318
G2
1
4 5
B
TO D BOARD FBT
CN312
+B
+B +80V +12V
7V
3.3V 5V
1
+B
2
+80V
4
+12V
6
7V
7
3.3V
8
5V
9
C
TO D BOARD CN604
D
TO D BOARD CN1103
E
TO N BOARD CN1003
TO MAGNETIC SENSOR UNIT
CN1400
WAKE UP
KEY SCAN
LED1 LED2
INPUT SW
T_AMB
VY VX
CN1401
VX VY
2 3 4 5
8 12 13 14
3
2
(USER CONTROL)
H3
Q1402
TH1400
5V
5V
S1403
INPUT1
INPUT2
S1401
LED DRIVE
Q1400
LED DRIVE
Q1401
S1400
S1402OKS1404–S1405
BRT+
+
G
A
CONT–
D1400
POWER
F
TO D BOARD CN1106
CN1603
GXSC
GYSC LCC NS IIC SDA
IIC SCL
4 5 6 7 8
L2
(CY, LCC)
4
3
6
7
1
2
21 20
+
+
IC1603 +
SDA SCL
IC1600
2
(1/2)
IC1600
8
(2/2)
4
IC1602
DAC
AO2 AO1 AO4 AO3
CN1601
CY4+
3
CY4–
4
CY3+
1
CY3–
2
CN1600
12LCC-NS (+)
LCC-NS (–)
IC1601
4
2
+
(1/2)
3
2 1 4 3
IC1601
6
8
+
(2/2)
7
IC1604
4
2
+
(1/2)
3
IC1604
6
8
+
(2/2)
7
1 2 3 4 5 6 7 8
CN1602
LCC-LT (+) LCC-LT (–) LCC-LB (+) LCC-LB (–) LCC-RT (+) LCC-RT (–) LCC-RB (+) LCC-RB (–)
LCC-NS
LCC-LT
LCC-LB
LCC-RT
LCC-RB
B-SS9342<AEP>-BD1-EPS05
21T3 (E) 4-1
G
TO D BOARD CN502
CN1101
H.DF
REFDC
XDC
HD OUT
HFBP
H BLK VS OUT HS OUT
PLL LOCK
IIC SDA IIC SCL
LCC_NS
HSAW_SW
H.LINBAL
GYSC
GXSC
V.DF
D.TILT
YSC XSC
HSHAPE
YDC POC
DCC2
VSAWN
33 37 34 36 15 11 13
20 19 22 24 16 21 23
38 39 40 32 35
12 10
1
7
2
5
DA
(DPU)
2
+
IC1102
AMP
3 4
IC1001
IC1101
1 2
3 21 23 35 36 38 39 40 41 43 44 45 48 49 50 51 52 53 54 63 27 26 64 58 59
5
7
+
6
61 62
DPU
HDF1 DCC2 XDC HDOUT FBP-IN H BLK V-IN H-IN LOCK-DET SDA SCL LCC_NS HSAW_SW PWM2 GYSC GXSC VDF VKEY YSC XSC HSHAPE YDC POC-OUT POC-IN DCC ASW1 ASW2 VSAWL VSAWH
I
TO D BOARD CN1104
CN1001
LB DET
IK SIGMA DDC SDA1 DDC SCL1
DDC GND1
DDC SDA2 DDC SCL2
DDC GND2
INPUT SW
IIC SDA IIC SCL
TXD RXD
KEY SCAN
LED1 LED2
PLL LOCK
POC
HV DET
ABL DET
G2
S6 S5 S4 S3 S2 S1
S0 PWR SW DGC SW
V.FBP
WAKE UP
ECO SW
22
32 34
7
9 11 13 15 17 29
1
3
2
4 35 33 31 39 40
6
8 10 12 14 16 18 24 26 28 23 25 30 36
5
P42/AN10
21
P41/AN09
51
P86/SDA1
52
P87/SCL1
71
P21/A1/A17
49
P84/SDA2
50
P85/SCL2
70
P20/A0/A16
80
P27/A7/A23
35
P80/SDA0/SI0
36
P81/SCL0/SO0
37
P82/TXD0
38
P83/RXD0
23
P42/AN11
79
P26/A6/A22
78
P25/A5/A21
34
P76/SCK0/INT3
31
P73/TB01N0/IN5
19
P57/AN07
20
P40/AN08
28
P70/TA1OUT
7
P36/TA7OUT
6
P35/TA61N
5
P34
4
P33/MAIT
3
P32/HWR
2
P31/WR
1
P30/RD
58
P04/AD4
60
P06/AD6
10
P61/CTS0
13
P51/AN01
9
P60/INT0
CPU
P54/AN04 P55/AN05 P56/AN06
P12/A10/AD10
P11/A9/AD9 P10/A8/AD8
RESET
X2
X1
16 17 18
IC1003
64 63 62
ROM
7
WC
6
SCL
5
SDA
4 3 2
CN1003
T_AMB VY VX
E
TO H3 BOARD CN1400
5V
46
41
43
I
O
G
X1001
16.9344MHz
IC1002 RESET
N
(
µ-COM
INVERTER
Q1001
)
B-SS9342<AEP>-BD2-EPS05
21T3 (E) 4-2
AC IN
DGC
I
TO N BOARD CN1001
G
TO DA BOARD CN1101
CN602
AC L
NC
AC N
CN601
DGC DGC
CN1104
LB DET
IK SIGMA DDC SDA1 DDC SCL1
DDC GND1
DDC SDA2 DDC SCL2
DDC GND2
ECO SW
INPUT SW
IIC SDA
IIC SCL
TXD RXD
WAKE UP KEY SCAN
LED1 LED2
PLL LOCK
POC
HV DET
ABL DET
G2 S6 S5 S4 S3 S2 S1
S0 PWR SW DGC SW
V.FBP
CN502
IIC SCL
IIC SDA
VSOUT HSOUT
H BLK GXSC GYSC
LCC NS
PLL LOCK
POC H.DF V.DF
VSAWN
DCC2
H.LINBAL
HSAW_SW
HSHAPE
REFDC
HD OUT
YDC
HFBP
XDC
D.TILT
YSC
XSC
1 2 3
1 4
32 34
7
9 11 13 15 17
5 29
1
3
2
4 36 35 33 31 39 40
6
8 10 12 14 16 18 24 26 28 23 25 30
19 20 11 13 15 21 23 22
7
5
1
2 10 12 16 24 32 33 34 35 36 37 38 39 40
F601
THP602
IIC SDA IIC SCL
TXD RXD
WAKE UP
KEY SCAN
LED1 LED2
PLL LOCK
POC
HV DET
ABL DET
G2
PWR SW DGC SW
V.FBP
IIC SCL IIC SDA VSOUT HSOUT
H BLK GXSC GYSC
LCC NS
PLL LOCK
POC H.DF V.DF
VSAWN
DCC2
H.LINBAL
HSAW_SW
HSHAPE
REFDC
HD OUT
YDC
HFBP
XDC
D.TILT
YSC
XSC
11
13
14
9
15
16
3.3V
5V
T501 :HDT
1
2
4 1
H DF OUT Q701-705
V DF OUT Q706, 707
17
7
6 14 11 12 18
+15V
IC640
+B DETECT ERROR AMP
D650
D652
IC401 V OUT
1
+
OUT
7
IC501 PWN CONT
SAWR
ERRIN REFIN HDIN MIX– MIX+ VREG9
12
IC654
12V REG
5 3 6
PWMOUT
MIXOUT
ERROUT
T701 :DFT
BUFF Q507
+B
+80V
+15V
+12V
-15V
7V
5V
3.3V
H OUT
Q505
3
10
9
H-SIZE FILTER SW
Q523
D.TILT
XSC
3.3V
YSC
XDC YDC REFDC
14
11 12
+B
HV REG SW
HV DRIVE Q903-904
G2 OUT
Q905
G2 MUTE
Q906
H-SIZE FILTER SW
Q524
IC701 CY AMP
3
INA–
4
INA+
6
INB+
7
INB–
IC702 CY AMP
5
–IN A (X)
4
+IN A (X)
3
+IN B (Y)
2
–IN B (Y)
10
STBY
IC901 HV CONT
H SAW GEN
+
Q901
IC503 AMP
5
7
+
6
G2 MUTE
Q907
Width
+
HV OUT
Q902
PIN DRIVE Q508-509
IOUTA OUTA OUTB IOUTB
OUT A (X)
OUT B (Y)
5
3
10
T902 :HRC
DEFLECTION , HDF, VDF,
D
HV, POWER SUPPLY
IC703
1 2 8 9
6
1
3.3V
1
+
2
ROTATION DRIVE
4
10
9 8 7 6 5 4 3 2 1
CN701
ROTATION+ ROTATION– XSC– XSC+ YSC– YSC+ XDC– XDC+ YDC– YDC+
ROTATION
CN604
+B
1
+B +80V +12V
7V
3.3V 5V
T901
4
1
2
8
6
:FBT
TO
PICTURE TUBE
HV
17
13
TO
FV
PICTURE
TUBE
14
15
16
FC
PICTURE
TUBE
11
12
TO
+B
2
+80V
4
+12V
6
7V
7
3.3V
8
5V
9
C
TO A1 BOARD CN312
CN510
G2
1
B
V DY
L510
+B
PIN OUT
Q506
:HOC
L509
:HCC
S501
(RASTER CENTER TAP SWITCH)
CN501
V+
1
V–
2
H–
4
H+
6
H DY
PH610
H DRIVE
Q504
4
3
T620
7
5
IC652
5
CTL
2
Vcc
T601 :LFT
RY603
S601
TH601
RY602
RELAY DRIVE
Q611
+15V +15V
IIC SDA IIC SCL VS OUT HS OUT H BLK
TXD RXD
WAKE UP
S6 S5 S4 S3 S2 S1 S0
KEY SCAN LED1 LED2
GXSC GYSC LCC NS IIC SDA IIC SCL
11 10
9 8 7 6
13
4 16 15
3
2
1
4
3
2
3
4
5
8
4
5
6
7
8
CN1102
DDC SDA1 DDC SCL1 DDC GND1 DDC SDA2 DDC SCL2 DDC GND2 ECO SW INPUT SW IIC SDA IIC SCL VS OUT HS OUT H BLK
CN1101 TXD RXD
CN1103
WAKE UP KEY SCAN LED1 LED2 INPUT SW
CN1106
GXSC GYSC LCC NS IIC SDA IIC SCL
TO A1 BOARD CN311
ECS
D
TO H3 BOARD CN1400
TO L2 BOARD CN1603
A
F
D610
AC RECT
L610 AFC
IC630 REG
PH630
OUT
ISENS
5
3
1
1
COMP
2
FB
4
RT/CT
8
VREF
4
32
DGC SW PWR SW
H.DF
V.DF
HFBP
DCC2 VSAWN
V.FBP HV DET ABL DET
G2
HD OUT
AC SEN
3
8
3
IC610 PFI
15103
1
2
9
REG SW
Q630
VCC SW
Q610
IC680
1
2 1
DRAIN
L SEN
CATHODE
4
3
2
1
PH620
4
32
H DRIVE BUFF
IC620 REG OUT
FB
VG (H)
VSENSE
VG (L)
T630 :SRT
5
6
8
1
Q501-503
VC2
OCP
VS VB
16 15 14 10 12
9
MAIN CONVERTER
OUT
Q641
MAIN CONVERTER
OUT
Q640
PROTECT
Q652
HSHAPE
HSAW_SW
S0 S1 S2 S3 S4 S5 S6
H.LINBAL
S CAP CANGE Q511-517
Q511-516
T504 :HST
T503 :LCT
H_SAW SW
Q521
SIZE DETECT BUFF
Q519
L502 :HLC
H LIN BAL SW
Q510
15V
B-SS9342<AEP>-BD3-EPS05
4-2. FRAME SCHEMATIC DIAGRAM
CN309
HD15D-SUB
INPUT2 (HD15)
CN307
HD15D-SUB
INPUT1 (HD15)
10
15
5
14
9
4
13
8
3
12
7
2
11
6
1
10
15
5
14
9
4
13
8
3
12
7
2
11
6
CN312
1
9P
WHT
5V
3.3V7V+12V
987654321
GND
+80VNC+B
+B
(VIDEO AMP, RGB OUT )
A1
CN311
17P
WHT
GND
IIC SDA
IIC SCA
GND
ECO SW
GND
DDC SDA1
DDC SCL1
DDC GND1
17161514131211
987654321
10
DDC SDA2
DDC SCL2
DDC GND2
GND
INPUT SW
VS OUT
HS OUT
H BLK
2P
CN318
G2
1
G2(NC)
2
HG H
RGB
PICTURE
TUBE
G2
G1
DA
(
DPU
987654321
5V
7V
+B
+B
NC
3.3V
GND
+12V
S2
DGC SW
(
+80V
D
S3
GND
GND
GND
HTR SW
PWR SW
µ-COM
DDC GND2
GND
HTR SW
GND
GNDS3DDC GND2S4DDC SCL2S5DDC SDA2S6DDC GND1G2DDC SCL1
)
CN604
9P
LED1
LED1
LB DET
LB DET
LED2
LED2
BLK
DEFLECTION,HDF,VDF, HV, POWER SUPPLY
S0
S1
+5V
V.FBP
INPUT SW
V.FBP
INPUT SWS0+5VS1DGC SWS2PWR SW
N
CN1101
40P
40
XSC
39
YSC
38
D.TILT
37
XDC
36
HFBP
35
YDC
34
HD OUT
33
REFDC
32
HSHAPE
31
+12V
30
NC
29
+12V
28
A.GND
27
3.3V
26
D.GND
25
D.GND
24
HSAW_SW
23
GXSC
22
LCC NS
21
GYSC
20
IIC SDA
19
)
IIC SCL
18
A.GND
17
A.GND
16
H.LINBAL
15
H BLK
14
NC
13
HS OUT
12
DCC2
11
VS OUT
10
VSAWN
9
NC
8
A.GND
7
PLL LOCK
6
A.GND
5
POC
4
A.GND
3
A.GND
2
V.DF
1
H.DF
TO ECS
AC IN
DGC
XSC YSC
D.TILT
XDC
HFBP
YDC
HD OUT
REFDC
HSHAPE
+12V
+12V
A.GND
3.3V D.GND D.GND
HSAW_SW
GXSC
LCC NS
GYSC IIC SDA IIC SCL
A.GND A.GND
H.LINBAL
H BLK
HS OUT
DCC2 VS OUT VSAWN
A.GND
PLL LOCK
A.GND
POC A.GND A.GND
V.DF
H.DF
CN502
40P
40 39 38 37 36 35 34 33 32 31 30
NC
29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14
NC
13 12 11 10
9
NC
8 7 6 5 4 3 2 1
CN1104
44P
4443424140393837363534333231302928272625242322212019181716151413121110
NC
CN1101
4P
WHT
1
D GND
2
+5V
3
RXD
4
TXD
CN602
3P
WHT
:VH
AC L
1
NC
2
AC N
3
CN601
4P
WHT
:VH
1
DGC
2
NC
3
NC
4
DGC
GND
NC
GNDNCNC
4443424140393837363534333231302928272625242322212019181716151413121110
CN1001
44P
S7
NC
NC
POC
GND
IK SIGMA
WAKE UP
PLL LOCK
KEY SCAN
POC
PLL LOCK
GNDS7WAKE UP
KEY SCAN
IK SIGMA
S4
CN1102
17P
BLK
S5
DDC SCL2
17161514131211
GND
IIC SDA
IIC SCA
S6
G2
DDC SDA2
DDC GND1
987654321
DDC SCL1
987654321
GND
ABL DET
ABL DET
ECO SW
DDC SDA1
DDC SDA1
987654321
10
GND
DDC SCL1
DDC SDA1
DDC SDA2
DDC GND1
RXD
IIC SCL
HV DET
ECO SW
HV DET
ECO SW
RXD
IIC SCL
DDC SCL2
DDC GND2
TXD
IIC SDA
TXD
IIC SDA
CN1003
6P
:S-MICRO (L)
T_AMB
LUMI (NC)
5V (NC)
GND
GND
VX VY
VS OUT
INPUT SW
1 2 3 4 5 6
HS OUT
H BLK
1
1P
CN504
1.2kV
CN1103
8P
WHT
1413121110 VX
VY
GND
GND
T_AMB
H3
(
USER CONTROL
INPUT SW 8765432
987654321
GND
INPUT SW
HV
CN701
10P
WHT
:S-MICRO
ROTATION+ ROTATION–
XSC– XSC+ YSC– YSC+ XDC– XDC+ YDC– YDC+
CN501
6P
WHT
:VH
V+
V– NC H– NC H+
CN1101
40P
1 2 3 4 5 6 7 8
+5V
GND
LED 2
LED 1
KEY SCAN
WAKE UP
+12V 1
+5V
GND
+12V
LED 2
LED 1
CN1400
WAKE UP
14P
KEY SCAN
CN1401
5P
1
GND
2
VX
3
VY
4
T_AMB
5
LUMI (NC)
6
5V (NC)
)
10
9 8 7 6 5 4 3 2 1
1 2 3 4 5 6
-15V +15V GND GXSC GYSC LCC_NS IIC SDA IIC SCL
MAGNETIC
SENSOR
ROTATION
V DY
H DY
CN1603
8P
WHT
1
-15V 2
+15V
3
GND
4
GXSC
5
GYSC
6
LCC_NS
7
IIC SDA
8
IIC SCL
(
CY, LCC
TO
L2
CN1601
4P
WHT
:S-MICRO
CY4+ CY4– CY3+ CY3–
CN1600
2P
WHT
:S-MICRO LCC-NS (+) LCC-NS (–)
CN1602 LCC-LT (+) LCC-LT (–)
LCC-LB (+)
LCC-LB (–)
LCC-RT (+) LCC-RT (–) LCC-RB (+) LCC-RB (–)
)
3 4 1 2
1 2
1 2 3 4 5 6 7 8
LCC-NS
LCC-LT
LCC-LB
LCC-RT
LCC-RB
B-SS9342<AEP>-KESSENZU-EPS05
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