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FILE NO.
SERVICE MANUAL
Color Digital Camera VPC-X360E
(Product Code : 126 251 01)
(U.K.)
VPC-X360EX
(Product Code : 126 251 02)
(Europe)
(PAL General)
VPC-X360
(Product Code : 126 251 03)
(U.S.A.)
(Canada)
Contents
1. OUTLINE OF CIRCUIT DESCRIPTION .................... 2
2. DISASSEMBLY ........................................................ 12
3. ELECTRICAL ADJUSTMENT .................................. 15
4. TROUBLESHOOTING GUIDE ................................. 20
5. PARTS LIST ............................................................. 21
CABINET AND CHASSIS PARTS 1 ........................ 21
CABINET AND CHASSIS PARTS 2 ........................ 22
ELECTRICAL PARTS .............................................. 23
ACCESSORIES ....................................................... 28
PACKING MATERIALS ............................................ 28
CIRCUIT DIAGRAM (Refer to the separate volume)
PRODUCT SAFETY NOTICE
The components designated by a symbol ( ! ) in this schematic diagram designates components whose value are of
special significance to product safety. Should any component designated by a symbol need to be replaced, use only the part
designated in the Parts List. Do not deviate from the resistance, wattage, and voltage ratings shown.
CAUTION : Danger of explosion if battery is incorrectly replaced.
Replace only with the same or equivalent type recommended by the manufacturer.
Discard used batteries according to the manufacturer's instructions.
NOTE : 1. Parts order must contain model number, part number, and description.
2. Substitute parts may be supplied as the service parts.
3. N. S. P. : Not available as service parts.
Design and specification are subject to change without notice.
SR662/E, EX, U REFERENCE No. SM5310090
1. OUTLINE OF CIRCUIT DESCRIPTION
1-1. CA-1 CIRCUIT DESCRIPTION
1. IC Configuration [Features]
IC903 (ICX204AK) CCD imager Independent storage and retrieval for each pixel
IC902 (74VHC04MTC) H driver Square pixel unit cell
IC904 (CXD1267AN) V driver XGA compatible
IC905 (AD9802) CDS/AGC, A/D converter R, G, B primary color mosaic filter
Continuous variable speed electronic shutter function
2. IC903 (CCD)
[Structure]
Interline type CCD image sensor
Pin 1
Optical size 1/3 inch format 2
Effective pixels 1034 (H) 779 (V)
Pixels in total 1077 (H) 788 (V)
Chip size 5.80 mm (H) 4.92 mm (V) V
Unit cell size 4.65 m (H) 4.65 m (H)
Optical black 8
Horizontal (H) direction: Front 3 pixels, Rear 40 pixels
2
Vertical (V) direction: Front 7 pixels, Rear 2 pixels H 34
Dummy bit number Horizontal : 29 Vertical : 1 Pin 9
Fig. 1-1.Optical Black Location (Top View)
Pin No. Symbol Pin Description Waveform Voltage
1 V 3 Vertical shift register gate clock -7.5 V, 0 V
2 V 2B Vertical shift register gate clock -7.5 V, 0 V, 15 V
3 V 1 Vertical shift register gate clock -7.5 V, 0 V
4 V 2A Vertical shift register gate clock -7.5 V, 0 V, 15 V
5, 6, 7, 10 GND GND
8 OS Image output
9 OD Output transister drain 15 V
Amplitude 22.5 V Ex. 6 V (Bias
11 SUB Board clock
level is different from every CCD)
12 OSUB Board bias DC (Different from every CCD) Ex. 6V
13 PL Protection transistor bias DC -7.5 V
14 RS Reset transister gate clock Amplitude 3.5 V Ex. 5 V, 10 V
(Different from every CCD)
15 H1 Horizontal shift register transfer clock 0 V, 3.5 V
16 H2 Horizontal shift register transfer clock 0 V, 3.5 V
Table 1-1. CCD Pin Description When sensor read-out
3. IC902 (H Driver) and IC904 (V Driver) 4. IC905 (CDS, AGC Circuit and A/D converter)
An H driver (IC902) and V driver (IC904) are necessary in The video signal which is output from the CCD is input to
order to generate the clocks (vertical transfer clock, horizon- Pins (26) and (27) of IC905. There are S/H blocks inside IC905
tal transfer clock and electronic shutter clock) which driver generated from the XSHP and XSHD pulses, and it is here
the CCD. that CDS (correlated double sampling) is carried out.
IC902 is an inverter IC which drives the horizontal CCDs (H1 After passing through the CDS circuit, the signal passes
and H2). In addition the XV1-XV4 signals which are output through the AGC amplifier. It is A/C converted internally into
from Pins (166), (167), (169) and (171) of IC102 are the ver- a 10-bit signal, and is then input to IC102 of the CA2 circuit
tical transfer clocks, and the XSG1 and XSG2 signals which board. The gain of the AGC amplifier is controlled by the volt-
is output from Pins (168) and (170) of IC102 is superimposed age at pin (29) which is output from IC102 of the CA2 circuit
onto XV1 and XV3 at IC904 in order to generate a ternary board and smoothed by the PWM.
pulse. In addition, the XSUB signal which is output from Pin
(165) of IC102 is used as the sweep pulse for the electronic
PBLK CLPDM PGACONT1 PGACONT2 SHP SHD ADCCLK
shutter, and the RG signal which is output from Pin (159) of 19 23 29 30 21 22 16
IC102 is the reset gate clock.
CLAMP TIMING
GENERATOR
PIN 27 PGA
CDS 10
26 2
DIN MUX S/H A/D DOUT
36 11
1A 1 14 VCC ADCIN
CLAMP 12 DRVDD
1Y 2 13 6A
REFERENCE AD9802 17 DVDD
2A 3 12 6Y 37 48 47 18 20 41 33 43
CMLEVEL VRT VTB STBY CLPOB ADCMODE ACVDD ADVDD
2Y 4 11 5A
Fig. 1-4. IC905 Block Diagram
3A 5 10 5Y
3Y 6 9 4A
GND 7 8 4Y
Fig. 1-2. IC902 Block Diagram
CPP1
1 CPP3 20
Change Pump
VH 19
2 CPP2
DCIN DC OUT
3 18
VSHT 17
4 XSHT
XV2
5 VL 16
XV1 V 2
6 15
XSG1 V 1
7 14
XV3 VM 13
8
V 3
9 XSG2 12
V 4
10 XV4 11
Fig. 1-3. IC904 Block Diagram
5. Transfer of Electric Charge by the Horizontal CCD
The transfer system for the horizontal CCD emplays a 2-phase drive method.
The electric charges sent to the final stage of the horizontal CCD are transferred to the floating diffusion, as shown in Fig. 1-5.
RG is turned on by the timing in (1), and the floating diffusion is charged to the potential of PD. The RG is turned off by the timing
in (2). In this condition, the floating diffusion is floated at high impedance. The H1 potential becomes shallow by the timing in (3),
and the electric charge now moves to the floating diffusion.
Here, the electric charges are converted into voltages at the rate of V = Q/C by the equivalent capacitance C of the floating
diffusion. RG is then turned on again by the timing in (1) when the H1 potential becomes deep.
Thus, the potential of the floating diffusion changes in proportion to the quantity of transferred electric charge, and becomes
CCD output after being received by the source follower. The equivalent circuit for the output circuit is shown in Fig. 1-6.
(1) H1 H2 H1 H2 H1 HOG RG
CCD OUT
PD
(1) (2) (3)
Floating diffusion 3.5V
H1
0V
(2) H1 H2 H1 H2 H1 HOG RG
3.5V
H2
0V
CCD OUT
PD 13.5V
RG
0V
(3) H1 H2 H1 H2 H1 HOG RG
RG pulse peak signal
RG pulse leak signal
CCD OUT
Black level
CCD OUT Signal voltage
Fig. 1-5. Horizontal Transfer of CCD Imager and Extraction of Signal Voltage
Reset gate pulse
12V Pre-charge drain bias PD
Direction of transfer
H Register
Voltage output
Electric
charge
Floating diffusion gate is
floated at a high impedance.
C is charged
equivalently
Fig. 1-6. Theory of Signal Extraction Operation
1-2. CA2 CIRCUIT DESCRIPTION
1. Circuit Description 1-7. 8-bit D/A circuit (Audio)
1-1. Scannning converter (Interlace converter) This circuit converts the audio signals (analog signals) from
This circuit uses the function of a 64-Mbit SDRAMs to con- the microphone to 8-bit digital signals.
vert the non-interlaced signal which is output from the CCD
into an interlaced signal for the video monitor. 1-8. 8-bit A/D circuit (Audio)
The audio signals which were converted to digial form by the
1-2. Camera signal processor 8-bit A/D circuit are temporarily to a sound buffer and then
This comprises circuits such as the digial clamp circuit, white recorded in the SSFDC card. During playback, the 8-bit D/A
balance circuit, circuit, color signal generation circuit, ma- circuit converts these signals into analog audio signals.
trix circuit and horizontal aperture circuit.
1-9. Sound buffer
1. Digital clamp circuit Audio memory
The optical black section of the CCD extracts 16-pixel aver-
aged values from the subsequent data to make the black level 1-10. LCD driver
of the CCD output data uniform for each line. The 16-pixel The Y/C signals which are input to the LCD driver are con-
averaged value for each line is taken as the sum of the value verted to RGB signals, and the timing signal which is neces-
for the previous line multiplied by the coefficient k and the sary for LCD monitor display and the RGB signals are then
value for the current line multiplied by the coefficient 1-k. supplied to the LCD monitor.
2. White balance circuit 1-11. LCD monitor
This circuit controls the white balance by using the AWB judge- This is the image display device which displays the image
ment value computed by the CPU to control the gain for each signals supplied from the LCD driver.
R, G and B pixel based on the CCD data which has been
read. 1-12. UART
This circuit is used for transmitting serial data to a PC. The
3. circuit interface is RS-232C-compatible.
This circuit performs (gamma) correction in order to maintain
a linear relationship between the light input to the camera 1-13. SSFDC control
and the light output from the picture screen. This reads data from the SSFDC card and stores it in SDRAM,
and writes out the image data stored in SDRAM. In addition,
4. Color generation circuit error correction is carried out when the data is read.
This circuit converts the CCD data into RGB signals.
1-14. MJPEG compression
5. Matrix circuit Still and continuous frame data is converted to JPEG format,
This circuit generates the Y signals, R-Y signals and B-Y sig- and movie images are compressed and expanded in MJPEG
nals from the RGB signals. format.
6. Horizontal aperture circuit 2. Outline of Operation
This circuit is used generate the aperture signal. When the shutter opens, the reset signals, TEST0, TEST1
and the serial signals ("take a picture" commands) from the
1-3. SDRAM controller 8-bit microprocessor are input and record operation starts.
This circuit outputs address, RAS, CAS and AS data for con- When the TG drives the CCD, picture data passes through
trolling the SDRAM. It also refreshes the SDRAM. the A/D and is then input to the ASIC as 10-bit data. This data
then passes through the DCLP, AWB, shutter and circuit,
1-4. PIO after which it is input to the SDRAM. The AWB, shutter,
The expansion parallel port can be used for functions such and AGC value are computed from this data, and two expo-
as stroboscope control and LCD driver control. sures are made to obtain the optimum picture. The data which
has already been stored in the SDRAM is read by the CPU
1-5. SIO (Serial control) and color generation is carried out. Each pixel is interpolated
This is the interface for the 8-bit microprocessor. from the surrounding data as being either R, G or B primary
color data to produce R, G and B data. At this time, correction
1-6. TG, SG block of the lens distortion which is a characteristic of wide-angle
This is the timing generation circuit which generates the clocks lenses is carried out. Aperture correction is carried out, and
(vertical transfer clock and electronic shutter clock) which drive in case of still picture the data is then compressed by the
the CCD. JPEG method and in case of picture it is compressed by
MJPEG method and is written to SSFDC card. When the data
is to be output to an external device, it is read JPEG picture
data from the SSFCD card and output to PC via the UART.
3. LCD Block
During EE, gamma conversion is carried out for the 10-bit
RGB data which is input from the A/D conversion block of the
CCD to the ASIC in order that the revised can be displayed
on the video. The YUV of 640 x 480 is then transferred to the
SVRAM.
The data which has accumulated in the SDRAM is after D/A
conversion is carried out by SDRAM control circuit inside the
ASIC , makes Y/C signal, the data is sent to the LCD panel
and displayed.
If the shutter button is pressed in this condition, the 10-bit
data which is output from the A/D conversion block of the
CCD is sent to the SDRAM (DMA transfer), and is displayed
on the LCD as a freeze-frame image.
During playback, the JPEG image data which has accumu-
lated in the SSFDC card is converted to RGB signals. In the
same way as for EE, the data is then sent to the SDRAM,
after which D/A conversion is carried out inside the ASIC,
and then the data is sent to the LCD panel and displayed.
The LCD driver is converted Y/C signals to RGB signals from
ASIC, and these RGB signals and the control signal which is
output by the LCD driver are used to drive the LCD panel.
The RGB signals are 1H transposed so that no DC compo-
nent is present in the LCD element, and the two horizontal
shift register clocks drive the horizontal shift registers inside
the LCD panel so that the 1H transposed RGB signals are
applied to the LCD panel.
Because the LCD closes more as the difference in potential
between the VCOM (common polar voltage: fixed at DC) and
the R, G and B signals becomes greater, the display becomes
darker; if the difference in potential is smaller, the element
opens and the LCD become brighter. In addition, the bright-
ness and contrast settings for the LCD can be varied by means
of the serial data from the ASIC.
1-3. PW1 POWER CIRCUIT DESCRIPTION
1. Outline 3. Digital 3.3 V Power Output
This is the main power circuit, and is comprised of the follow- 3.3 V (D) is output. Feedback for the 3.3 V (D) is provided to
ing blocks. the switching controller (Pins (1) of IC501) so that PWM con-
Switching controller (IC501) trol can be carried out.
Digital and analog system and LCD 5.0 V system power out-
put (L5010, Q5002, D5013, C5061) 4. 5 V System Power Output
Digital 3.3 V system power supply (L5017, Q5009, D5007, 5 V (D), 5.1 V (A) and 5 V (L) are output. Feedback for the 5
C5062) V (D) is provided to the switching controller (Pin (12) of IC501)
Analog and LCD system power supply (Q5007, T5001) so that PWM control can be carried out.
Backlight power supply output (L5005, Q5008, D5014, C5005)
5. Analog and LCD System Power Output
2. Switching Controller (IC501) 15.0 V (A), -7.5 V (A), 12.4 V (L) and 15 V (L) are output.
This is the basic circuit which is necessary for controlling the Feedback for the 15.0 V (A) with view mode and 12.4 V (L)
power supply for a PWM-type switching regulator, and is pro- with play mode is provided to the switching controller (Pin
vided with four built-in channels, only CH1 (digital 3.3 V), CH2 (25) of IC501) so that PWM control can be carried out.
(5 V system), CH3 (analog and LCD system) and CH4 (back-
light system) are used. Feedback from 3.3 V (D) (CH1) ,5.0 V 6. Backlight Power Supply output
(D) (CH2), +15.0 V (A), +12.4 V (L) (CH3) and 5.8 V (L) (CH4) 5.8 V (L) is output. Feedback is sent to pins (36) of the switch-
power supply outputs are received, and the PWM duty is var- ing controller (IC501) for PWM control to be carried out.
ied so that each one is maintained at the correct voltage set-
ting level.
2-1. Short-circuit protection circuit
If output is short-circuited for the length of time determined
by the condenser which is connected to Pin (17) of IC501, all
output is turned off. The control signal (P ON, P(A) ON and
LCD ON) are recontrolled to restore output.
1-4. PW1 STROBE CIRCUIT DESCRIPTION
1. Charging Circuit 2. Light Emission Circuit
When UNREG power is supplied to the charge circuit and the When RDY and TRIG signals are input from the ASIC expan-
CHG signal becomes High (3.3 V), the charging circuit starts sion port, the stroboscope emits light.
operating and the main electorolytic capacitor is charged with
high-voltage direct current. 2-1. Emission control circuit
However, when the CHG signal is Low (0 V), the charging When the RDY signal is input to the emission control circuit,
circuit does not operate. Q5409 switches on and preparation is made to let current
flow to the light emitting element. Moreover, when a STOP
1-1. Power switch signal is input, the stroboscope stops emitting light.
When the CHG signal switches to Hi, Q5406 turns ON and
the charging circuit starts operating. 2-2. Trigger circuit
When a TRIG signal is input to the trigger circuit, D5405
1-2. Power supply filter switches on, a high-voltage pulse of several kilovolts is gen-
L5401 and C5401 constitute the power supply filter. They erated inside the trigger circuit, and this pulse is then applied
smooth out ripples in the current which accompany the switch- to the light emitting part.
ing of the oscillation transformer.
2-3. Light emitting element
1-3. Oscillation circuit When the high-voltage pulse form the trigger circuit is ap-
This circuit generates an AC voltage (pulse) in order to in- plied to the light emitting part, currnet flows to the light emit-
crease the UNREG power supply voltage when drops in cur- ting element and light is emitted.
rent occur. This circuit generates a drive pulse with a frequency
of approximately 50-100 kHz. Because self-excited light omis- Beware of electric shocks.
sion is used, the oscillation frequency changes according to
the drive conditions.
1-4. Oscillation transformer
The low-voltage alternating current which is generated by the
oscillation control circuit is converted to a high-voltage alter-
nating current by the oscillation transformer.
1-5. Rectifier circuit
The high-voltage alternating current which is generated at
the secondary side of T5401 is rectified to produce a high-
voltage direct current and is accumulated at electrolytic ca-
pacitor C5412 on the main circuit board.
1-6. Voltage monitoring circuit
This circuit is used to maintain the voltage accumulated at
C5412 at a constance level.
After the charging voltage is divided and converted to a lower
voltage by R5417 and R5419, it is output to the SY1 circuit
board as the monitoring voltage VMONIT. When this VMONIT
voltage reaches a specified level at the SY1 circuit board, the
CHG signal is switched to Low and charging is interrupted.
1-5. SY1 CIRCUIT DESCRIPTION
1. Configuration and Functions
For the overall configuration of the SY1 circuit board, refer to the block diagram. The configuration of the SY1 circuit board
centers around a 8-bit microprocessor (IC301).
The 8-bit microprocessor handles the following functions.
1. Operation key input, 2. Mode LCD display, 3. Clock control, 4. Power ON/OFF, 5. Storobe charge control
Pin Signal I/O Outline
1 CHG VOL I Strobe charge voltage input (analog input)
2 NOT USED - -
3~7 SCAN IN 0~4 I Key matrix input
8 AVDD - A/D converter analog power terminal
9 AVREF I A/D converter standard voltage input terminal
10 STBY (R) LED O Standby LED (red) ON/OFF signal L : LED light
11 STBY (G) LED O Standby LED (green) ON/OFF signal L : LED light
12 VSS - GND
13 SELF LED (R) O Self-timer LED (red) ON/OFF signal L : LED light
14~19 NOT USED - -
20 AVREF ON O A/D standard power ON/OFF signal L : ON
21 NOT USED - -
22 CHG ON O Flash charge ON/OFF signal H : ON
23~30 NOT USED - -
31 VSS - GND
32~69 NOT USED - -
70 P (A) ON O DC/DC converter (analog) ON/OFF signal H : ON
71 P ON O DC/DC converter (digital) ON/OFF signal H : ON
72 DIN CONNECT I DIN jack connect detection signal L : Connection
73 NOT USED - -
74 AV JACK I AV output cable connection detection signal L : Connection
75 SI I Serial communication data input (ASIC)
76 SO O Serial communication data output (ASIC)
77 SCK O Serial communication clock output (ASIC)
78 IC - Connect to Vss
79 XOUT O Main clock oscillation terminal (4 MHz)
80 XIN I Main clock oscillation terminal
81 VDD - Power supply terminal
82 XCIN I Sub clock oscillation terminal (32.768 kHz)
83 XCOUT O Sub clock oscillation terminal
84 RESET I Reset input
85 BAT OFF I Battery OFF detection signal L : OFF
86 RXD I RS-232C RXD input terminal
87 S. REQ I Serial communication request signal L : Request
88~90 NOT USED - -
91~93 SCAN OUT 0~2 O Key matrix output
94 NOT USED - -
95 LCD ON O LCD monitor power ON/OFF signal H : ON
96 ASIC TEST 0 O ASIC reset control signal
97 ASIC RESET O ASIC reset signal L : Reset output
98 ASIC TEST 1 O ASIC reset control signal
99 AVSS - A/D converter GND power terminal
100 BATTERY I Battery voltage input (analog input)
Table 4-1. 8-bit Microprocessor Port Specification
2. Internal Communication Bus
The SY1 circuit board carries out overall control of camera operation by detecting the input from the keyboard and the condition
of the camera circuits. The 8-bit microprocessor reads the signals from each sensor element as input data and outputs this data
to the camera circuits (ASIC) or to the LCD display device as operation mode setting data. Fig. 4-1 shows the internal commu-
nication between the 8-bit microprocessor and ASIC.
S. REQ
ASIC SO ASIC
8-bit
32 bit
microprocessor
ASIC SI CPU
ASIC SCK
RESET
Fig. 4-1 Internal Bus Communication System
3. Key Operaiton
For details of the key operation, refer to the instruction manual.
SCAN
SCAN IN 0 1 2 3 4
OUT
0 MACRO
1 SHUTTER 1st SHUTTER 2nd CAMERA PLAY -
2 BARRIER CARD LID MODE SET TEST
Table 4-2. Key Operation
4. Power Supply Control
The 8-bit microprocessor controls the power supply for the overall system.
The following is a description of how the power supply is turned on and off. When the battery is attached, a regulated 3.3 V
voltage is normally input to the 8-bit microprocessor (IC301) by IC303, so that clock counting and key scanning is carried out
even when the power switch is turned off, so that the camera can start up again. When the battery is removed, the 8-bit micro-
processor operates in sleep mode using the backup capacitor. At this time, the 8-bit microprocessor only carries out clock
counting, and waits in standby for the battery to be attached again. When a switch is operated, the 8-bit microprocessor supplies
power to the system as required.
The 8-bit microprocessor first sets both the P (A) ON signal at pin (70) and the P ON signal at pin (71) to low, and then turns on
the DC/DC converter. After this, High signals are output from pin (97) so that the ASIC is set to the active condition. If the LCD
monitor is on, the LCD ON signal at pin (95) set to Low, and the DC/DC converter for the LCD monitor is turned on.
ASIC, RS232C 8bit MODE LCD
CCD
memory driver CPU LCD MONITOR
5 V (A), -7.5 V, 3.2 V 3.2 V 5V (L), 15 V,
Power voltage 3.3 V 3.3 V
+15 V etc. (ALWAYS) (ALWAYS) +12V etc.
Lens cover close OFF OFF OFF 32KHz OFF OFF
Power switch ON-
OFF OFF OFF 4MHz ON OFF
Auto power down
Lens Shutter switch ON ON ON ON OFF 4MHz ON OFF
cover
open Resolution, Flash,
OFF OFF OFF 4MHz ON OFF
Self timer switch ON
LCD finder ON ON ON 4MHz ON ON
Playback ON ON OFF 4MHz ON ON
Table 4-3. Camera Mode (Battery Operation)
ASIC, RS232C 8bit MODE LCD
CCD
memory Driver CPU LCD MONITOR
5 V (A), -7.5 V, 3.2 V 3.2 V 5 V (L)
Power voltage 3.3 V 3.3 V
+12 V etc. (ALWAYS) (ALWAYS) +12V etc.
Lens cover close OFF OFF OFF 32 KHz OFF OFF
Power switch ON-
OFF OFF OFF 4 MHz ON OFF
Auto power down
Take a picture ON ON ON OFF 4 MHz ON OFF
Lens
Erase image ON ON OFF 4 MHz ON OFF
cover
open
Download image ON ON OFF 4 MHz ON OFF
Continuous image ON ON ON 4 MHz ON OFF
Message from host ON ON ON 4 MHz ON OFF
Note) P. SAVE = Power save mode, 4 MHz = Main clock operation, 32 kHz = Sub clock operation
Table 4-4. Host Mode (Battery Operation)
2. DISASSEMBLY
2-1. REMOVAL OF CABINET ASSEMBLY (FRONT) AND CABINET ASSEMBLY (BACK)
6. Screw 1.7 x 3
7. Cabinet top
3. Back cabinet
13. Holder battery
12. Five screws
1.7 x 3
1. Four screws
2. Front cabinet
1.7 x 4
10. Holder
SSFDC
11. Holder terminal
5. Cover jack
8. Screw 1.7 x 3
9. Two screws
1.7 x 4
1. Two screws 1.7 x 4 4. Cover battery
2-2. REMOVAL OF SY1 BOARD, TB2 BOARD AND TB1 BOARD
1. Two screws 1.7 x 3
2. FPC
4. Connector 5. SY1 board
3. Three connectors
9. Unit control panel
8. Screw 1.7 x 3
7. TB2 board
6. Screw 1.7 x 3 10. Screw 1.7 x 3
11. TB1 board
2-3. REMOVAL OF LENS VF AND PW1 BOARD
1. Two screws 1.7 x 3
2. Lens VF
4. Connector
5. Connector
8. Reflector
3. Two screws
1.7 x 3
6. Three
screws
1.7 x 3
7. Holder chassis PW1
9. PW1 board
2-4. REMOVAL OF LCD, CA2 BOARD AND CA1 BOARD
8. Holder
9. CA2 board
chassis
CA2
3. Four screws
7. Two 1.7 x 3
screws
1.7 x 3
6. Two
connectors
2. LCD
4. Connector
11. Holder
chassis
CA1
5. Screw 1.7 x 3
1. FPC
12. Two screws
1.7 x 6
13. Screw
1.7 x 4
10. Three screws 14. CA2 board
1.7 x 3
2-5. BOARD LOCATION
CA2 board
SY1 board
TB2 board TB1 board
PW1 board
CA1 board
3. ELECTRICAL ADJUSTMENT
3-1. Table for Servicing Tools 3-4. Setup
1. System requirements
Ref. No. Name Part code Windows 95 or 98
J-1 Color viewer 5,100 K IBM R -compatible PC with 486 or higher processor
VJ8-0007
CD-ROM drive
J-2 Siemens star chart
3.5-inch high-density diskette drive
J-3 Calibration software VJ8-0166 Serial port with standard RS-232C interface
J-4 Extension cord VJ8-0151 8 MB RAM
Hard disk drive with at least 15 MB available
Note: J-1 color viewer is 100 - 110 VAC only. VGA or SVGA monitor with at least 256-color display
J-2 Siemens star chart is the same as before models.
2. Installing calibration software
J-1 J-2 1. Insert the calibration software installation diskette into your
diskette drive.
2. Open the explorer.
3. Copy the DSC Cal folder on the floppy disk in the FD drive
to a folder on the hard disk.
3. Color Viewer
Turn on the switch and wait for 30 minutes for aging to take
place before using Color Pure.
4.Computer screen during adjustment
J-3 J-4
Calibration Upload LCD
R Bright B Bright VCOMDC
AWB Firmware
Focus Image RGB Offset Gain VCOMPP
UV Matrix Tint Phase
Initialize
LCD Type H AFC Test
Firmware Version:
3-2. Equipment
1. Oscilloscope
2. Digital voltmeter
3. AC adaptor
4. IBM R -compatible PC
5. DC regulated power supply
3-3. Adjustment Items and Order
1. IC501 Frequency Adjustment
2. 5.0 V (D) Voltage Adjustment
3. 3.3 V (D) Voltage Adjustment
4. 12.4 V (L) Voltage Adjustment 1
5. 12.4 V (L) Voltage Adjustment 2
6. 5.8 V (L) Voltage Adjustment
7. CCD Defect Defect Adjustment
8. AWB Adjustment
9. Flange-back Adjustment
10. LCD Panel Adjustment
10-1. LCD H AFC Adjustment
10-2. LCD RGB Offset Adjustment
10-3. LCD Gain Adjustment
10-4. LCD Blue Brightness Adjustment
10-5. LCD Red Brightness Adjustment
3-5. Connecting the camera to the computer
1. Turn off both camera and computer.
2. Locate the port cover on the side of the camera. Press on the arrows and slide the cover down to open it.
3. Line up the arrow on the cable connector with the notch on the camera's serial port. Insert the connector.
4. Locate a serial port on the back of your computer. You may have two serial ports labeled COM1 and COM2, or the ports may
be labeled with icons. If you have two serial ports available, use port 1 to connect your camera.
5. Line up the serial connector on the cable with one of the serial ports on your computer, and insert the connector.
6. Turn on the camera and your computer system.
To COM1 or COM2 serial port
Serial cable
AC adaptor
3-6. Adjust Specifications 3. 3.3 V (D) Voltage Adjustment
[PW1 board (Side A/B)] Measuring Point CL533 or CL553 or CL519
Measuring Equipment Digital voltmeter
ADJ. Location VR502
ADJ. Value 3.30 0.03 V
VR501 VR502
Adjustment method:
1.Adjust with VR502 to 3.30 0.03 V.
CL524
CL515
CL554 4. 12.4 V (L) Voltage Adjustment 1
VR504 CL519
VR505 CL536 Measuring Point CL524 or CL554
CL530
Measuring Equipment Digital voltmeter
VR503 VR506
ADJ. Location VR505
ADJ. Value 12.40 0.05 V
CL512 Adjustment method:
1. Set the play mode.
2. Adjust with VR505 to 12.40 0.05 V.
CL553
5. 12.4 V (L) Voltage Adjustment 2
CL533
Measuring Point CL524 or CL554
Measuring Equipment Digital voltmeter
ADJ. Location VR504
ADJ. Value 12.40 0.05 V
Note: Adjustment method:
1. Voltage adjustment is necessary to repair in the PW1 board 1. Set the view mode, and turn on the LCD.
and replace the parts. 2. Adjust with VR504 to 12.40 0.05 V.
2. Power voltage set about +3.0 V.
Preparation: 6. 5.8 V (L) Voltage Adjustment
1. Connect CN103 on the CA2 board and CN502 on the PW1
Measuring Point CL530 or CL536
board with extension cord.
2. Open the barrier switch.
Measuring Equipment Digital voltmeter
3. Set the view mode, and turn on the LCD. ADJ. Location VR506
4. Carry out initialization and display the through image on the ADJ. Value 5.80 0.05 V
LCD screen.
Adjustment method:
1. IC501 Oscillation Frequency Adjustment 1. Adjust with VR506 to 5.80 0.05 V.
Measuring Point CL512 7. CCD Defect Detect Adjustment
Measuring Equipment Frequency counter Adjustment method:
ADJ. Location VR501 1. Set the camera mode, and turn on the power switch to open
the lens cover.
ADJ. Value 200 1 kHz
2. Double-click on the DscCalV123b.
Adjustment method: 3. Select CCD Defect on the LCD "Test", and click the "Yes".
1. Adjust with VR501 to 200 1 kHz. 4. After the adjustment is completed, OK will display.
5. Close the lens cover.
2. 5.0 V (D) Voltage Adjustment
Measuring Point CL515
Measuring Equipment Digital voltmeter
ADJ. Location VR503
ADJ. Value 5.10 0.05 V
Adjustment method:
1. Adjust with VR503 to 5.10 0.05 V.
8. AWB Adjustment Preparation:
POWER switch: ON
Adjusting location:
Flange-back adjustment screw (Fig. 1)
Adjust the adjustment screw by turning it through the hole pro-
vided in the CA1 board. If this adjustment screw is turned
counter-clockwise, the focal length of the lens will decrease,
and if it is turned clockwise, the focal length will increase.
Adjustment method:
Serial cable
1. Display the image taken by the camera on the screen of a
computer.
2. Set the focus switch at the normal position.
3. Project two Siemens star charts at a distance of 1.0 meters
and 0.3 meters infront of the lens.
4. Turn the adjustment screw until the Siemens star which is
Camera
0 - 18 cm 1.0 meters away is exactly in focus. Check that the Siemens
star which is 0.3 meters from the front of the lens is out of
All white pattern focus at this time.
Color viewer 5,100K 5. Project the Siemens star chart at a distance of 0.3 meters
in front of lens. Check that it is out of focus at normal mode,
Preparation: and it is in focus at macro mode.
POWER switch: ON 6. This adjustment location is integrated with the iris mecha-
Adjusting method: nism. After adjusting, make sure that no load has been
1. Set the all white pattern so that it becomes a full picture. placed on the iris mechanism and harness.
(Do not enter any light.)
2. Double-click on the DscCalV123b. 10. LCD Panel Adjustment
3. Click the AWB, and click the Yes. [CA1 board (Side B)]
4. AWB adjustment value will appear on the screen.
5. Click the OK.
9. Frange-back Adjustment
CL426
CL425
CL424
Screw driver
Lens Adjustment screw
10-1. LCD H AFC Adjustment
Fig. 1 Preparation:
POWER switch: ON
Adjusting method:
Focus switch 1. Double-click on the DscCalV123b .
2. Select 0 on the LCD "H AFC".
3. While watching the LCD monitor, adjust "H AFC" so that the
edge of the LCD adjustment frame are the same distance
Macro position
from the left and right edge of the LCD screen. (A = B)
Normal position
Fig. 2
LCD
adjustment
LCD screen A B frame
VG
FPC
10-2. LCD RGB Offset Adjustment CL424 waveform
Adjusting method:
1. Adjust LCD "RGB offset" so that the amplitude of the CL424
waveform is 7.5 Vp-p 0.3 V.
VG 0.2 V
7.5 Vp-p
0.3 V
CL426 waveform
10-5. LCD Red Brightness Adjustment
Adjusting method:
CL424 waveform
1. Adjust LCD "R Bright" so that the amplitude of the CL425
waveform is 0.2 V with respect to the CL424 (VG) wave-
10-3. LCD Gain Adjustment form.
Adjusting method: Note:
1. Adjust LCD "Gain" so that the amplitude of the CL424 wave- 10-2. LCD RGB Offset adjustment and 10-3. LCD Gain ad-
form is 4.0 Vp-p 0.15 V. justment should always be carried out first.
Note:
10-2. LCD RGB Offset adjustment should always be carried
out first.
VG
4.0 Vp-p
0.15 V
CL424 waveform
CL424 waveform
10-4. LCD Blue Brightness Adjustment
Adjusting method: VG 0.2 V
1. Adjust LCD "B Bright" so that the amplitude of the CL426
waveform is 0.2 V with respect to the CL424 (VG) wave-
form.
Note:
10-2. LCD RGB Offset adjustment and 10-3. LCD Gain ad- CL425 waveform
justment should always be carried out first.
4. TROUBLESHOOTING GUIDE
POWER LOSS INOPERTIVE TAKING INOPERATIVE
CLOSE PUSH SHUTTER
BARRIER SW BARRIER SW ON NORMAL BUTTON
OPEN
HIGH IC301-4, 5 NO CHECK
CHECK S6002,
IC301-4, 93 (SCAN IN 0, 1) S3029, D3064,
CN302, D3069, R3021
PULSE INPUT R3021, R3022
LOW YES
LOW IC301-70, 71 LOW
IC302-7 (UP UNREG) CHECK IC132, PW1 CHECK IC301
(P ON, P(A) ON)
HIGH HIGH
IC301-81 LOW IC301-96, 97, 98 NO
CHECK IC302 CHECK IC301, IC101
(VDD) HIGH
HIGH YES
LOW SERIAL NG
IC301-84 CHECK IC301,
CHECK IC302, R3051 COMMUNICATION
(RESET) R3001, R3003, IC101
IC301-75~77, 87
HIGH OK
IC301-85 LOW
CHECK R3052 CHECK IC101
(BAT OFF)
HIGH
IC301-80 NO
CHECK X3001
OSCILLATION
YES
IC301-82 NO CHECK X3002,
OSCILLATION R3004, C3001, C3002
YES
CHECK IC301
NO PICTURE
CLK (114MHz) YES MAIN CLOCK FOR SYSTEM OPERATION
OSCILLATION NO OPERATION IF ABSENT
CHECK L1105 CHECK IC111, L1101, L1105 and X1101
YES
SD CLK (57 MHz) NG MAIN CLOCK FOR SDRAM (IC106)
OSCILLATION NO OPERATION IF ABSENT FROM IC121
IC106-35 CHECK IC101, IC106 and C1061
YES
NG INCORRECT HANDSHAKING BETWEEN 8-BIT
IC101-111, 114
CPU AND RS-232C
(IC301-75, 76)
CHECK EACH INTERFACE
OK
CHECK ASIC AND
MEMORY PIN
5 . PARTS LIST
LOCATION PARTS NO. DESCRIPTION LOCATION PARTS NO. DESCRIPTION
CABINET & CHASSIS PARTS 1 16 636 055 5853 HOLDER TERMINAL-SR662/J
17 636 056 0956 DEC MONITOR-SR662/E
1 636 056 2479 ASSY,COVER LENS-SR662/E 18 636 055 9080 ASSY,CABINET BACK-SR662/J
2 636 055 5600 COVER FRONT-SR662/J 19 636 055 5938 KNOB POWER-SR662/J
3 636 055 5785 DEC WINDOW VF-SR662/J 20 636 057 0214 SPRING COMP RELEASE-662/J
4 636 055 5792 DEC STRAP-SR662/J 21 636 055 9042 ASSY,BUTTON SHUTTER-662/J
5 636 055 9066 ASSY,CABI FRONT-SR662/J 22 636 056 0932 CABINET TOP-SR662/E
6 636 055 5846 HOLDER COVER LENS-SR662/J 23 636 055 5990 SLIDE KNO