RCA DTV306, DTV307 Diagram
Television
Tech-Line Tip
TTT01-002
The information contained herein is provided solely to assist in the diagnosis of the problem
described. It is not intended as a modification or alteration of the product.
DATE: 6/4/01
MODEL/CHASSIS: DTV306/307
TOPIC:Putting Chassis in Service Position
1. Remove the yoke board as shown in picture 1.
2. Remove the DM-1 power supply as shown in picture 2.
3. Swing the left end of the chassis out as shown in picture 3.
4. Turn the chassis over to get to the bottom as shown in picture 4.
Picture 1
Product Safety Information
Product Safety information is contained in the appropriate TCE Service Data covering models/chassis referenced herein. All specified Product
Safety requirements and testing shall be complied with prior to returning equipment to the customer. Servicers who defeat safety features or fail to
perform safety checks may be liable for any resulting damages and may expose themselves and others to possible injury.
First Edition First Printing
Copyright 2001
Printed in U.S.A. Trademark(s) ® Registered Marca(s) Registrada(s)
Page 1 of 3 (TTT01-002)
Picture 2
Picture 3
Product Safety Information
Product Safety information is contained in the appropriate TCE Service Data covering models/chassis referenced herein. All specified Product
Safety requirements and testing shall be complied with prior to returning equipment to the customer. Servicers who defeat safety features or fail to
perform safety checks may be liable for any resulting damages and may expose themselves and others to possible injury.
First Edition First Printing
Copyright 2001
Printed in U.S.A. Trademark(s) ® Registered Marca(s) Registrada(s)
Page 2 of 3 (TTT01-002)
Picture 4
Product Safety Information
Product Safety information is contained in the appropriate TCE Service Data covering models/chassis referenced herein. All specified Product
Safety requirements and testing shall be complied with prior to returning equipment to the customer. Servicers who defeat safety features or fail to
perform safety checks may be liable for any resulting damages and may expose themselves and others to possible injury.
First Edition First Printing
Copyright 2001
Printed in U.S.A. Trademark(s) ® Registered Marca(s) Registrada(s)
Page 3 of 3 (TTT01-002)
Television
Tech-Line Tip
TTT01-006
The information contained herein is provided solely to assist in the diagnosis of the problem
described. It is not intended as a modification or alteration of the product.
DATE: 8/9/01
MODEL/CHASSIS: DTV300, DTV306, and DTV307
TOPIC:
TOPIC: Troubleshoot the DM-1
SYMPTOM: No signal in the menu
If when trying to view Satellite channels you get “searching for signal” the problem may be that the 13/18 voltage
coming from the DM-1 is missing. Place the unit is standby and hook a voltmeter on the satellite RF input (center is
positive and outside shield is ground). Watch for the voltage to go from 13 volts to 18 volts. If the voltage is there, the
problem is at the dish. You need to check the multi-switch or the LNB’s. If the voltage is not there, you need to troubleshoot
the DM-1 power supply.
Product Safety Information
Product Safety information is contained in the appropriate TCE Service Data covering models/chassis referenced herein. All specified Product
Safety requirements and testing shall be complied with prior to returning equipment to the customer. Servicers who defeat safety features or fail to
perform safety checks may be liable for any resulting damages and may expose themselves and others to possible injury.
First Edition First Printing
Copyright 2001
Printed in U.S.A. Trademark(s) ® Registered Marca(s) Registrada(s)
Page 1 of 1 (TTT01-006)
Television
Tech-Line Tip
TTT01-007
The information contained herein is provided solely to assist in the diagnosis of the problem
described. It is not intended as a modification or alteration of the product.
DATE: 8/9/01
MODEL/CHASSIS: DTV306 and DVT307
TOPIC:
TOPIC: CR14608
SYMPTOM: Power light comes ON but no power
When you press the power button and the power LED stays on but you have no power, you need to check VCC on
pin 16 and 29 of U13101. If the voltage is low, go to CR14608 and check for 5 volts. Upon checking the diode, if the
voltage is missing, change the diode. This diode is located in the standby power supply and supplies voltage to the micro
continuously.
Product Safety Information
Product Safety information is contained in the appropriate TCE Service Data covering models/chassis referenced herein. All specified Product
Safety requirements and testing shall be complied with prior to returning equipment to the customer. Servicers who defeat safety features or fail to
perform safety checks may be liable for any resulting damages and may expose themselves and others to possible injury.
First Edition First Printing
Copyright 2001
Printed in U.S.A. Trademark(s) ® Registered Marca(s) Registrada(s)
Page 1 of 1 ()
SAFETY PRECAUTIONS
DO NOT OPERATE THIS INSTRUMENT OR PERMIT IT TO BE
OPERATED WITHOUT ALL PROTECTIVE DEVICES
INSTALLED AND FUNCTIONING. SERVICERS WHO DEFEAT
SAFETY FEATURES OR FAIL TO PERFORM SAFETY CHECKS
MAY BE LIABLE FOR ANY RESULTING DAMAGE, AND MAY
EXPOSE THEMSELVES AND OTHERS TO POSSIBLE INJURY.
READ AND COMPLY WITH ALL CAUTION AND SAFETYRELATED NOTES ON OR INSIDE THE RECEIVER CABINET,
AND THE RECEIVER CHASSIS, OR ON THE PICTURE TUBE.
SAFETY GLASSES SHOULD BE USED WHEN SERVICING
ELECTRONIC INSTRUMENTS. INADVERTENTLY
OVERSTRESSING COMPONENTS MAY CAUSE THEM TO
SHATTER, DISCHARGING SMALL PARTICLES.
DESIGN ALTERATION WARNING - Do not alter or add to the
mechanical or electrical design of this TV receiver. Design alterations and
additions may alter the safety characteristics of this receiver and create a
hazard to the user. Design alterations or additions may void the
manufacturer's warranty and may make you, the servicer, responsible for
personal injury or property damage resulting therefrom.
BEFORE RETURNING AN INSTRUMENT TO THE CUSTOMER,
always make a safety check of the entire instrument, including, but not
limited to, the following items:
FIRE AND SHOCK HAZARD
1. Never release a repaired unit unless all protective devices such as
insulators, barriers, covers, strain reliefs and other protective hardware
have been installed in accordance with the original design.
2. Be sure that there are no cabinet openings through which an adult or a
child might be able to insert their fingers and contact a hazardous
voltage. Such openings include, but are not limited to: (a) spacings
between picture tube and cabinet mask, (b) excessively wide cabinet
ventilation slots, and (c) an improperly fitted or incorrectly secured
back cover.
3. Observe original lead dress. Take care to restore leads to their original
dress. Make sure that leads are not in contact with sharp edges or
thermally hot parts. Always inspect in all areas for pinched, out-ofplace or frayed wiring. Do not change spacing between adjacent
components, or between components and printed-circuit board. Check
AC power cord for damage.
4. Be certain to remove loose solder balls and all other loose foreign
particles.
5. Check components, parts and/or wiring for physical evidence of
damage, overheating or deterioration, and replace if necessary.
Determine the cause of damage and/or overheating and, if necessary,
take corrective action to remove any potential safety hazard.
6. Parts Replacement - Many TV electrical and mechanical parts have
special safety-related characteristics, some of which are often not
evident from visual inspection, and the protection they give cannot
necessarily be obtained by replacing them with components rated for
higher voltage, wattage, etc. Parts that have special safety characteristics
are identified in this service data by a ( ) on schematics and in the parts
list. Use of a substitute replacement that does not have the same safety
characteristics as the recommended replacement part in the service data
parts list may create shock, fire and/or other hazards. Always consult
the appropriate current service literature for the latest information.
7. Some TV receiver chassis' normally have 85VAC (RMS) between
chassis and earth ground, regardless of the AC plug polarity. Some TV
receiver chassis' are electrically connected directly to one conductor of
the AC power cord. Some TV receiver chassis' have a secondary ground
system in addition to the main chassis ground. This secondary ground
system is not isolated from the AC power line. The two ground systems
are electrically separated by insulating material that must not be
defeated or altered. Thus, when servicing any unit always use a separate
isolation transformer for the chassis. Failure to use a separate isolation
transformer may expose the servicer to possible shock hazard, and may
cause damage to servicing instruments.
8. Many electronic products use a polarized AC line cord (one wide pin on
the plug). Defeating this safety feature may create a potential hazard to
the servicer and the user. Extension cords which do not incorporate the
polarizing feature should never be used.
PICTURE TUBE IMPLOSION WARNING - The picture tube in this
receiver employs integral implosion protection. For continued implosion
protection, replace the picture tube only with one of the same type number.
Do not remove, install, or otherwise handle the picture tube in any manner
without first putting on shatterproof goggles equipped with side shields.
People not so equipped must be kept safely away while picture tubes are
handled. Keep the picture tube away from your body. Do not handle the
picture tube by its neck. Some "in-line" picture tubes are equipped with a
permanently attached deflection yoke; because of potential hazard, do not
try to remove such "permanently attached" yokes from the picture tube.
X-RADIATION AND HIGH VOLTAGE LIMITS - Because the picture
tube is the primary source of X-radiation in solid-state TV receivers, it is
specially constructed to prohibit X-radiation emissions. For continued Xradiation protection, a replacement picture tube must be the same type as the
original. The picture shields, mounting hardware and lenses (projection TV)
may also perform an X-radiation protection function, and they must be
correctly in place. Anode connectors contain an X-radiation shield - use only
the manufacturer's specified anode connectors. High voltage must be
measured each time servicing that involves power supply, horizontal
deflection or high voltage circuits is performed. Correct operation of the Xradiation circuits must also be confirmed each time these circuits are
serviced (X-radiation circuits may also be called "horizontal disable" or
"hold-down" circuits). Read and apply high voltage limits and, if the chassis
is so equipped, the X-radiation protection circuit specifications. These
limits and specifications are given on instrument labels and are included in
this service data. High voltage is maintained within specified limits by closetolerance safety-related components (and adjustments) in the high voltage
circuit. If high voltage exceeds specified limits, check each safety related
component specified on the schematic and take corrective action.
ANTENNA LEAKAGE RESISTANCE CHECK - With the instrument
AC plug removed from the AC source, connect an electrical jumper across
the two AC plug prongs. Place the instrument AC switch (if applicable) in
the "on" position. Connect one lead of an ohmmeter to the AC plug prongs
and touch the other ohmmeter lead, in turn, to each (exposed) antenna input
terminal screw and/or coaxial connector. If the measured resistance is less
than 1.0 Megohm, or greater than 5.2 Megohm, an abnormality exists which
must be corrected before the instrument is returned to the customer. Repeat
this test with the AC switch in the "off" position.
reading
should be
< 0.5mA
earth
ground
2-wire
cord
DEVICE
UNDER
TEST
also test with
plug reversed
(use ac adapter
plug as required)
probe all
exposed
metal
surfaces
LEAKAGE
CURRENT
TESTER
+-
LEAKAGE CURRENT HOT CHECK FOR 2-WIRE OR 3-WIRE
GROUNDED CORD SETS - With the instrument completely reassembled,
plug the AC line cord into the mains AC outlet at normal line voltage via a
non-polarized adapter. DO NOT GROUND THE 3RD PRONG OF THE
ADAPTER AND DO NOT USE AN ISOLATION TRANSFORMER. Use
a leakage current tester or metering system that complies with American
National Standards Institute (ANSI) C101.1 Leakage Current for
Appliances and with Underwriters Laboratories (UL) 1492 (Section 67).
With the instrument AC switch first in the "on" position and then in the "off"
position, measure from a known earth ground (metal water pipe, conduit,
etc.) to all exposed metal parts of the instrument (antennas, handle bracket,
metal cabinet, screwheads, metallic overlays, control shafts, etc.). Any
current measured must not exceed 0.5 milliampere. Reverse the adapter plug
in the outlet and repeat the test. ANY MEASUREMENTS NOT WITHIN
THE LIMITS SPECIFIED HEREIN INDICATE A POTENTIAL
SHOCK HAZARD THAT MUST BE ELIMINATED BEFORE
RETURNING THE INSTRUMENT TO THE CUSTOMER OR
BEFORE CONNECTING THE ANTENNA OR ACCESSORIES. If a
leakage current tester is not available, connect a 1.5 Kohm, 10 Watt resistor,
in parallel with a 0.15 µF, 150V capacitor, between earth ground and each
exposed metal part of the instrument (as shown above). Use an AC voltmeter
with at least 5000 ohm/volt sensitivity to measure the potential across the
resistor. The potential measured for any exposed metal surface must not
exceed 0.75 volts.
Page 1-2
DTV307
MODEL-TO-MAJOR ASSEMBL Y CROSS REFERENCE
KEY TO MAJOR ASSEMBLIES
I1 - I/O PCB (1552392A)
B1 - Frame Comb PCB (1552390A)
M1- Deflection/Power Supply PCB (1553100B)
C1 - Red CRT driver PCB (1558634B)
O1 - Front A/V PCB (1552388A)
C2 - Green CRT driver PCB (1558635B)
P1 - Adapter PCB (1558640C)
C3 - Blue CRT driver PCB (1558636B)
R1 - IR Receiver PCB (1550627A)
D1 - DM1 Assembly
D2 - DM1-CR Assembly
S1 - Deflection SIP PCB (1552391A)
F1 - Front Panel Assembly PCB (1550420C)
H1 - Convergence Amp PCB (1558574A)
T1 - 2nd Tuner/IF PCB(1507271O)
V1 - Digital Convergence Module PCB (1558637B)
CROSS REFERENCE
HD65W20JX1 ..................................... B1,C1,C2,C3,D2,F1,H1,I1,M1,O1,P1,R1,S1,T1,V1
HD65W20YX1 .................................... B1,C1,C2,C3,D2,F1,H1,I1,M1,O1,P1,R1,S1,T1,V1
P61310JX1 .......................................... B1,C1,C2,C3,D2,F1,H1,I1,M1,O1,P1,R1,S1,T1,V1
P61310JX2 .......................................... B1,C1,C2,C3,D1,F1,H1,I1,M1,O1,P1,R1,S1,T1,V1
P61310JX3 .......................................... B1,C1,C2,C3,D1,F1,H1,I1,M1,O1,P1,R1,S1,T1,V1
P61310JX4 .......................................... B1,C1,C2,C3,D2,F1,H1,I1,M1,O1,P1,R1,S1,T1,V1
PS65000JX2 .................................... B1,C1,C2,C3,D1,F1,H1,I1,M1,O1,P1,R1,S1,T1,V1
SPECIFICATIONS
General Specifications
Power Requirements: 95-132VAC, 50-60Hz
Power Consumption: 250 watts maximum
RF Specifications
Tuning System: Quartz-controlled multiband
frequency synthesis
Band Coverage: VHF channels 2-13
UHF channels 14-69
Cable channels 1-125
Frequency Coverage: 54-806 MHz
Antenna Inputs: 75-ohm UHF/VHF
Sensitivity: 10uV
DBS IF Tuning Range
IF Tuning Range 950 - 1450 Mhz
Audio Specifications
Frequency Response: 50-20,000 Hz (@ rated output)
Stereo Modes: Dbx stereo, Enhanced SRS Au x
Audio In: 250mVRMS typical,
A/V Input: 500mVRMS typical
Input Impedance: 50Kohms (source impedance
Power Output: 10 watts/channel
Fixed Audio Output: 250mVRMS into 10Kohms
Headphones: 16 ohms recommended
Remote Control
Transmission System: Digitally encoded infrared light
Battery Life: One year normal use
2.25VRMS maximum
should be < 2Kohms)
RMS into 8 ohms <0.5% THD
Video Specifications
Aux Video In: 1Vp-p, 75 ohms, neg sync
SVHS Luma In: 1Vp-p, 75 ohms, neg sync
SVHS Chroma In: 286mVp-p burst, 75 ohms
Aux Video Out: 1Vp-p, 75 ohms, negative sync
A/V Input: 1Vp-p, 75 ohms, neg sync
Other Inputs: Component Video (Y, PR, PB)
Specifications subject to change without notice.
Page 1-3
DTV307
SCHEMATIC NOTES
1 . Resistor values are in ohms (K = X1,000; Meg = X1,000,000). Tolerance is 5%, unless otherwise specified.
[ ] Indicates a flat (type 1206) surface-mounted device; 1/8 watt unless otherwise specified.
/ \ Indicates a flat (type 0805) surface-mounted device; 1/10 watt unless otherwise specified.
(no markings) indicates 1/4 watt, 5% tolerance axial-leaded device, unless otherwise specified.
2 . Capacitor values 1.0 and above are in picofarads; values less than 1.0 are in F, unless otherwise specified.
• • Indicates a cylindrical surface mounted device; 50 volt unless otherwise specified.
[ ] Indicates a flat (type 1206) surface-mounted device; 50 volt unless otherwise specified.
/ \ Indicates a flat (type 0805) surface-mounted device; 50 volt unless otherwise specified.
(no markings) indicates a radial- or axial-leaded device; 50 volt unless otherwise specified.
3 . DC voltages measured with NTSC color bar signal applied (via RF channel 3), except for audio voltages, which are measured
with MTS stereo 1KHz signal applied. Voltages in parentheses ( ) indicate standby mode.
4 . Waveforms measured with NTSC color bar signal applied (via RF channel 3), except for audio waveforms, which are measured
with MTS stereo 1KHz signal applied.
5 . Special symbols:
Indicates schematic zone locator Indicates service test point
Indicates wire-wrap stake Indicates connection via point-to-point wire
Indicates jumper wire (top side) Indicates zero ohm chip (bottom side)
Indicates "hot" ground Indicates "cold" ground
SERIAL NUMBER LOCA TION
Serial Number/Model Number Location on Chassis
Page 1-4
DTV307
Circuit Protection
Fusible Device Circuit Protected Physical Location
F14200 (6.0 A, 125V) AC Input Power Supply PCB, Left rear chassis
F14100 (3.0 A, 125V) AC Input DM1 Power Supply PCB, Left rear
COMPONENT NUMBERING SYSTEM
Serviceability of this chassis is enhanced by prominent road mapping on the top and bottom of the circuit boards. The
component numbering system relates to general circuit areas as follows:
11300 Series - Audio Outputs
11400 Series - Audio Input Switching
11500 Series - Audio Compression
11700 Series - SRS Audio
11800 Series - Audio TVB
11900 Series - Audio Power Amp, AVR
13100 Series - System Control (Control)
13200 Series - I/O Control
13400 Series - User Controls (Front Panel Assembly)
14100 Series - Power Supply (Regulator)
14200 Series - Power Supply (AC Input)
14300 Series - Deflection SIP
14400 Series - S-Cap Switch
14500 Series - Vertical
14600 Series - Standby Power Supply
14700 Series - Horizontal, HV
14800 Series - Scan
16300 Series - Frame Comb
16500 Series - Video Switching
17100 Series - 2nd
17300 Series - 2nd Tuner
Tuner
17400 Series - 2nd Tuner, PLL
18100 Series - F2PIP
18500 Series - Video I/O
19100 Series - Adapter
19300 Series - Convergence Amps
19500 Series - Digital Convergence
19700 Series - Convergence Power Supply
22300 Series - Video Control
22400 Series - Digital Interface
24500 Series - LNB Power Supply
24800 Series - Deflection SIP
25100 Series - Red CRT Drive
25300 Series - Green CRT Drive
25500 Series - Blue CRT Drive
26100 Series - FAV
27900 Series - 2nd Tuner IF
32100 Series - 2nd Tuner IF Out
38300 Series - Sync Processing
41100 Series - Fan Shutdown
Page 1-5
DISASSEMBLY PROCEDURES
Back Panel Removal
The cabinet back panel is held in place with several 1/4" hex
head screws. The number of (and placement of) screws varies
with the cabinet design. Remove screws as necessary to
release the cabinet back panel.
Mirror Removal
1. Remove the screen assembly.
2. Remove four screws located on the back of the
instrument holding the screen assembly.
Chassis Assembly Removal
1. Remove the back cover.
2. Remove two 1/4" hex screws holding the chassis to the
bottom of the cabinet.
3. Disconnect cables as necessary to service. Most of the
cables can be left connected for servicing by releasing the
wire ties and holders. Remove the DM1 Power Supply
for better access.
Note: Lead dress is critical on this chassis. Make sure all
cables, wires etc, are returned to their original lead
dress. See lead dress photos at the end of this
section.
I/O Board Panel Removal
1. Remove the back panel.
2. Remove four screws holding the upper half of the I/O
board panel and remove.
3. Remove the remaining hex screws and four torx screws.
4. Release one tab on each side of the panel and remove.
DM1 Module Removal
1. Remove the back panel.
2. Release tabs on each side of the DM1 Power Supply and
remove.
3. Remove two screws holding main chassis assembly.
4. Remove two screws holding DM1 to chassis.
5. Lift up and slide out of chassis.
6. Remove three screws holding DM1 mounting bracket to
chassis assembly.
7. Disconnect cables and remove DM1 from chassis.
Speaker Grill Assembly Removal
Pull the speaker grill assembly away from the front of the
instrument.
Screen Assembly Removal
1. Remove the speaker grill.
2. Disconnect the in-line connector coming from the Auto
Convergence sensors.
3. Remove the hex screws located along the bottom of the
screen assembly and back of the instrument.
4. Pull out slightly on the bottom of the screen assembly
and lift the assembly up to remove.
5. Remove two hex screws holding FPA assembly to screen
frame.
6. Unplug cable to Front A/V assembly.
CRT Removal
Note: Be sure to mark the location and orientation of the
tube assemblies as they are removed. When
reassembling, position the assemblies back to their
original position.
1. Remove the screen assembly.
2. Remove the 1/4" hex head screws securing the top CRT
access panel (located on top of the CRT's) and remove
the panel.
3. Remove the 1/4" hex head screws securing the front CRT
access panel (located on the front bottom of the cabinet)
and remove panel.
4. Loosen the screw near the bottom of the CRT neck
securing the CRT driver circuit board.
LOOSEN
SCREW
Fig. 2-1 Loosen screw to remove CRT driver circuit board
5. Pull the CRT driver circuit board off the end of the tube.
6. Carefully mark the location of the SVM coil and remove.
When reinstalling the SVM coil, the pad with the white
lead soldered to it should be placed on the top of the
tube(over the spacing bead) between the 2nd and 3rd
grids (Fig 2-2 on page 2-2).
WHITE LEAD PAD
Page 2-1
DISASSEMBLY PROCEDURES (Continued)
WHITE LEAD PAD
YOKE CLAMP
SCREW
Fig. 2-2 SVM coil placement
7. Loosen the screw on the yoke clamp and remove the
yoke(Fig 2-3).
MOUNTING BOLTS
Fig. 2-4 Mounting bolts location
10. Remove the grounding strap and spring.
11. Pull the CRT straight up out of the frame to remove.
YOKE CLAMP SCREW
Fig. 2-3 Yoke clamp
8. Release the anode lead from the HV splitter by pulling the
lead straight out (do not twist). Do not remove the anode
lead from the CRT.
9. Remove the four mounting bolts(Fig. 2-4).
Yoke Replacement
1. Perform steps 1 thru 7 under "CRT Removal".
2. Remove the hot melt glue from the four tabs on the
plastic housing.
3. Release the four tabs and remove the housing.
4. Unsolder the yoke and convergence leads taking note of
the color and orientation of the leads.
Second Tuner Circuit Board Removal
1. Twist the tabs to remove the Second Tuner circuit board.
Side Fan Removal
1. Disconnect P41125.
2. Twist one tab on each side of the fan assembly.
3. Pull the top of the fan out first, then the rest of the
assembly to remove.
Page 2-2
DISASSEMBLY PROCEDURES (Continued)
Critical Lead Dress
Page 2-3
DISASSEMBLY PROCEDURES (Continued)
Critical Lead Dress
Page 2-4
DTV307
CHIP COMPONENT REMOVAL
Replacement Procedure for Chip Removal
The following procedures are recommended for the
replacement of the chip components used in this unit.
Failure to follow these procedures may lead to damage to
the copper traces and pads on the printed circuit boards.
1.Preparation for replacement
a. Soldering Iron: Use a pencil-type soldering iron
using less than 30 watts.
b. Solder Type: Eutectic Solder, Tin 63%/Lead
37%, is recommended.
c. Soldering Time: Do not apply heat for more than
4 seconds.
d. Preheating: Chip capacitors must be preheated
before installation. (130 degrees - 150 degrees
C).
Note: Chip component must not be reused after removal.
Excessive mechanical stress and rubbing of the
component electrode must be avoided.
2. Removing the chip component (Fig. 2-3):
Grasp the chip component body with tweezers and
alternately apply heat to both electrodes.
Note: Do not attempt to lift the component off the board
until the component is completely disconnected
from the board by a twisting action. Attempting to
remove the component before it has completely
been disconnected can break the copper foil on
the printed circuit board.
3. Installing a chip component
a. Presolder the contact points on the circuit board
(Fig. 2-4).
Fig.2-4, Chip Component Presolder
b. Hold the component in position with tweezers and
solder the electrodes as shown (Fig.2-3).
Figure 2-3, Removing Chip Components
When the solder on both electrodes has melted,
remove the chip component with a twisting motion.
Fig. 2-3 - Chip Component Installation
Note: Do not glue the replacement chip component to the
circuit board.
Page 2-5
DTV307
ALIGNMENT PROCEDURES
Operating Conditions
Unless otherwise noted, the following conditions must be
observed when aligning the DTV307 chassis:
1. Chassis must be operated from a 120VAC isolation
transformer, with line voltage set to 120VAC (±2.0V).
2. Picture controls (black level, contrast, etc.) must be set to
factory presets via the Picture Quality menu.
3. Procedures must be performed in the sequence given.
4. A 10X probe must be used for oscilloscope and
frequency measurements.
5. Minimum warm-up time is 10 minutes.
Required Test Equipment
- Dual-Trace Oscilloscope
- Digital Voltmeter
- Frequency Counter
- Audio Signal Generator
- NTSC Signal Generator (B&K 1249, or equivalent)
- MTS Signal Generator (B&K 2009, or equivalent)
- Sweep/Marker Generator (or Standard Signal Generator)
- TAG001 Service Generator (stock # 215568)
- YPrPb Signal Generator (DVD player with YPrPb)
- DC Power Supply (5.0V/0.25A) for TAG001
- Chipper Check® software
- Chipper Check® interface box and computer
All alignments with the exception of basic color temp
require the use of Chipper Check® software and interface box.
X-Ray Shutdown Check
The following procedure should be performed prior to, and
upon completion of service:
1. Set Black Level and Contrast to maximum. Momentarily
apply a short between the shutdown test points
(JW14901- located at back edge of chassis) and ground.
The instrument must shutdown immediately, then turn
back on after ~ 2 seconds.
2. Apply and maintain a short between the shutdown test
points. The instrument must shutdown immediately and
remain shutdown (the instrument will attempt to restart
three times, then remain off).
3. Remove the short from JW14901.
4. Enter the Service Mode and reset the error code
parameter(s) to "0".
Entering the TV Service Mode Using the Front Panel
Controls
1. Press and release the POWER button to turn the
instrument on.
2. Simultaneously press and hold the TV/DIRECTV
and the Channel Down Buttons on the front of the TV.
The instrument will display the following menu:
The CH ∧ and CH ∨ buttons on the front panel (or the
P: 0 V: 0
remote transmitter) are used to change the parameter (P)
number. The VOL + and VOL - buttons are used to change the
value (V).
NOTE: Attempting to change the parameter number (using
CH ∧ or CH ∨) at this point will cause the instrument
to exit the service mode. A valid security code must
be entered (using VOL + or VOL -) before selecting
an alignment parameter.
Security Codes
When the service mode is first turned on, the parameter will
be "0", which does not correspond to an alignment. This is the
security code parameter, the purpose of which is to prevent
accidental entry into the parameter groups. The value (V)
must be set to 76 for Front panel access to Chassis
Alignments. The value (V) must be set to 80 for Digital
Convergence mode. The value (V) must be set to 90 for the
Warranty Clock. The value (V) must be set 200 for Chipper
Check®. Once Chipper Check® mode (V=200) is selected, the
Chipper Check® interface box will take control of the
instrument and the front panel will become inoperative.
Once a security code has been set, pressing CH ∧ or CH will
result in the following display:
Service Mode
Many of the alignments for this chassis are software-driven;
adjustments are made by modifying parameter values using
Chipper Check and the service menu. When parameter values
are modified, the corresponding T-chip registers, tuner
registers and EEprom locations are updated.
A list of the software alignment parameters accessable
using the front panel is shown in Table 2. The remainder of the
alignments require Chipper Check®. Even though some of the
geometry alignments are available through the front panel
service menu, adjustment is not recommended. Alignment in
one mode will interact and affect the displays of the other
modes.
Page 3-1
P: YY V: ZZZ
Where: YY = parameter number
ZZZ = current value
At this point, the CH ∧ and CH ∨ buttons can be used to
change the parameter number and the VOL + and VOL buttons can be used to change the value of the parameter
selected.
DTV307
ALIGNMENT PROCEDURES (Continued)
Error Codes
If certain failures occur in the chassis, error codes will be
stored in the chassis EEprom. These error codes are displayed
in parameters "1", "2" and "3". Parameter "1" stores the error
code for the first failure experienced by the instrument.
Similarly, parameter "2" stores the error code for the second
failure. Parameter "3" is automatically updated to display the
error code for the most recent failure experienced by the
instrument. Error codes are summarized in Table 1.
The presence of a "0" in the error code values indicates that
no failures have occurred since the time when the error code
parameters were reset. These error codes can (and should) be
reset to "0" after servicing with the VOL + and VOL - buttons.
Because a failure of a bus IC is a possible reason for needing
service, normal acknowledgment checking is disabled in the
service mode. If an IIC device has failed, its address will be
stored in the error code area.
Exiting The Service Mode
The service mode can be exited at any time by pressing the
INFO button on the remote (except when in ChipperCheck
mode). No additional steps are required to write new data into
the EEprom(s); new data is entered as parameter values are
changed.
CHASSIS ALIGNMENT
The DTV307 chassis requires the use of ChipperCheck®, a
TV/PC interface box, and a suitable computer (min. 486DX/
33MHz PC with 8Meg memory recommended) for the
majority of the alignments. Basic geometry and color
temperature are the only alignments accessable through the
front panel. These adjustments have been included in this
service manual as front panel procedures but can also be
performed using ChipperCheck®.
ChipperCheck® software and the TV/PC interface box are
available from:
AKB Mode (Parameter 27)
Do not change front panel adjustment parameter 27, AKB
mode. These are used for factory alignments only. 00 is the
default setting. All other adjustment values may set at
nominal or half of their full range values when there is a
question of what value is needed to begin alignments.
High Voltage Adjustment
The high voltage in this instrument is very critical and
requires special test equipment to measure and adjust. Field
alignment is not recommended. If one of the following
components is replaced the remainder of the components
listed must be replaced at the same time. These components
are packaged together in a kit (see parts list for stock number):
R14767, R14778, R14780, R14776 and R14777. Adjustment of
high voltage will not be necessary.
Note: To remove the high voltage leads from R14767, twist
the lead (at least 360deg) while pulling up.
®
XRP Adjustment
The XRP circuit in this instrument requires special test
equipment to measure and adjust. Field alignment is not
recommended. If one of the following components is replaced
the remainder of the components listed must be replaced at the
same time. These components are packaged together in a kit
(see parts list for stock number): CR14900, R14900, R14901,
R14902, R14904, R14906 and Q14901. Adjustment of XRP
will not be necessary.
Vertical Movie Mode (Parameter 14)
1. Always set to "0".
Vertical Slope/Vertical Start Scan (Parameters 15, 16, 17)
These parameters are preset at the factory and should not
be aligned.
TCE Publications
10003 Bunsen Way
Louisville, KY 40299
Tel. 502-491-8110
Instructions for the operation of ChipperCheck® software
and connection of the TV/PC interface are included as
context-sensitive help files in the ChipperCheck® software.
Focus Adjustment
1. Tune the instrument to receive a crosshatch signal.
2. Preset Contrast to maximum.
3. Set the value of parameter 41(RGB output mode) to 02.
4. Adjust the Green Mechanical Focus control, located on
the CRT assembly for best overall focus.
5. Adjust the Green Electrical Focus control, located
behind the speaker grill for best overall focus.
6. Repeat procedure for the red (value 01) and blue(value
03) CRT's.
Page 3-2
Scan ZVS
1 . Apply an NTSC flat white field to AUX 1.
2. Connect a DVM to the +76VRUN power supply
(C14111+).
3. Adjust R14101 for 76 + 0.1VDC.
DTV307
ALIGNMENT PROCEDURES (Continued)
rorrE
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1seYliaFrewoPlaitinI--
3seYnuRV21+--
6ebyaMhctiwSoediV-S1NUR00561UeruliaFylppuSroCI
7seYssoLnacS--noitcelfeDnacSfossoL
9seYCIoediV1NUR00322UeruliaFylppuSroCI
01ebyaMROPPIP2F1NUR00181UeruliaFylppuSroCI
11ebyaMredoceDoeretS2NUR10713UeruliaFylppuSroCI
21ebyaMdehctaLRVA--evitcARVA
31seYdeppotSnaF--10131U
61seY
81seYsuBybdnatSCII--10131UeruliafatadrokcolcCII
02seY
22reveN
42reveN
52reveN
62syawlA
54/44ebyaMCIPIP2F1NUR00181UeruliaFylppuSroCI
56/46ebyaMCADFIPIP2NUR20972UeruliaFylppuSroCI
76/66ebyaMCADrenuTniaM1NUR20623UeruliaFylppuSroCI
86ebyaMCADnoitcelfeD2NUR00842UeruliaFCI
37/27ebyaMcorPCNYS2NUR00383UeruliaFylppuSroCI
921/821ebyaMredoceDoeretS1NUR10713UrorrEylppuSroCI
431ebyaM
631ebyaMredoceDCSTN1NUR00322UeruliaFylppuSroCI
631ebyaMBVT2NUR00811UeruliaFylppuSroCI
041ebyaM
161/061ebyaMMORPEEO/IYBDTS20131UeruliaFylppuSroCI
761/461ebyaM
761/461ebyaM
961/861ebyaM
781/681ebyaMCIDSO1NUR20231UeruliaFylppuSroCI
291ebyaMLLPrenuTPIP2NUR10471UeruliaFylppuSroCI
491ebyaMCADFIPIP2NUR20972UeruliaFylppuSroCI
691ebyaMLLPrenuTniaM1NUR10552UeruliaFylppuSroCI
891ebyaMCADFIniaM1NUR20623UeruliaFylppuSroCI
022ebyaMorciMmetsyS--10131U
rewoP
lataF
rorrE suB eciveD noitidnoC
nuRV21+
tuoporD
nuRV21+
rotinoM
ro1nuRCII
rorrEsuB2nuR
kcatSerawtfoS
wolfrevO
er'uoY-sekirtS-4
derruccOtuO
ecnegrevnoC
rorrEytiraP
ecnegrevnoC
detlaHpooL
ecnegrevnoC
evitcanItuptuO
VAetisopmoC
hctiwS
noitcelfeD
rossecorP
renuTniaM
MORPEE
noitcelfeD
MORPEE
renuTdn2
MORPEE
--10131UeruliafatadrokcolcCII
--10131U
--10131UorciMybdetceteDtluaF
--20591U
--20591U
--20591U
1NUR10561UeruliaFylppuSroCI
2NUR05341UeruliaFylppuSroCI
1NUR10623UeruliaFylppuSroCI
2NUR45341UeruliaFylppuSroCI
2NUR30972UeruliaFylppuSroCI
nuRV21+kcehC
noitalugeRnuRV21+kcehC
tiucriCtceteDnaFronaF
eruliaF
teseR.snoitidnoCsuoiraV
.metsys
edoMtnerruCrofMORPEE
detpurroCsi
tonpooLecnegrevnoC
ylreporPgnitarepO
situptuOecnegrevnoC
evitcanI
snoitacinummuoCoN
10131UneewteB
20591Udna
Table 1 - Service Menu Error Codes
Page 3-3
DTV307
ALIGNMENT PROCEDURES (Continued)
Parameter # Para m eter Na m e Value Range
00 Service M ode E ntry 76 S et V:76, then in cr em e n t P :
01 Err or Dete ct io n ( 1s t)
02 Error Detection (2nd)
03 Error D e tec tion (la st)
04 Ho rizo ntal P hase 00 .. 63
05 Width Align 00 .. 63
06 Width 00 .. 63
07 E/W P arabola 00 .. 63
08 E/W Trap 00 .. 07
09 E/W Corne r 00 .. 6 3
10 Vertical O ffset 00 .. 07
11 Vertical Amp A lign 00 .. 63
12 V e rtical A m p D elta 00 .. 15
13 Ve rtical C enter 00 .. 63
Notes/Comments/Nominal
Values
Note: Changes VerticalAmpDelta
EEPROM, and Updates VerticalAmp
14 V ertical Movie Mode 00 .. 02 0=N ormal; 1=M ovie1; 2=Movie2
15 Vertical Slope MSB 00 .. 255
16 Vertical Slope LSB 00 .. 255
17 V er t ical S ta r t S c a n 00 .. 59
18 Red Cutoff 00 .. 255
19 Green Cutoff 00 .. 255
20 Blue C utoff 00 .. 255
21 Video Mode Cutoff 00 .. 255
22
23 Blue Drive 00 .. 127
24 Video Mode Light Output 00 .. 117
25 Text Mode Cutoff 00 .. 255
26 Text Mode Light Output 00 .. 107
27 AKB M ode 00 .. 01
Red Drive
00 ..127
00 = Off; 01 = On
28 Red Cutoff Overide 00 .. 255
29 Green Cutoff Overide 00 .. 255
30 Blue Cutoff O veride 00 .. 255
31 Cutoff (Overide) 00 .. 255
Table 2 - Service Menu Chart
Page 3-4
DTV307
ALIGNMENT PROCEDURES (Continued)
32 Comb D/A (Composite) 00 .. 127
33 FPIP Cont rast (Composite) 00 .. 127
34 FPIP Fine T int (Com posite) 00 .. 07
35 FPIP Saturation (Composite) 00 .. 127
36 Comb D/A (S-Video) 00 .. 127
37 FP IP Contrast (S-Video) 00 .. 127
38 FPIP Fine Tint (S-Video) 00 .. 255
39 FPIP Saturation (S-Video) 00 .. 127
40 Digicon Bus Control 00 .. 01
4 1 R GB Out put Mo de 0 0 . . 0 3
0 0 = e n able co mmunica tio n bet ween
Convergence Micro and Digital
Co n v e r gen c e Micro;
01 = Disable communicatio ns
0 = N o r mal
01 = Re d
02 = Green
03 = Blue
00 Digital Convergence Mode 80
00 P TV Sensor P ositioning 82
00
00
00 Warranty Clock Menu 90 Security Pass Number for W arranty M enu
PTV Restore Digital Convergence Factory
Alignment Data
PTV Save Digital Convergence Factory
Alignment Data
83
84
Securit y P ass Num ber fo r Convergence
Mode
Securit y P ass Num ber for
Sensor Positioning
Sec urit y P ass Num ber f or
Restore Factory Align Data
Securit y P ass Number for Save
Alignment Data
Table 2 (continued) - Service Menu Chart
Page 3-5
DTV307
ALIGNMENT PROCEDURES (Continued)
DM1 Service Menu
A seperate Service Menu is included in the DM1 module.
The purpose of this service menu is to assist the technician in
diagnosing problems with the DM1 module.
Entering the DM1 Service Menu
1. Press and Release the POWER button to turn the
instrument on.
2. Simultaneously press the MENU/OK and CHANNEL
DOWN on the Front Panel Assembly to enter the
service menu.
The instrument will display the following menu.
CAM ID - Also comes from the verifier software. Should be
same number as written o the CAM.
DEMOD SIGNAL - If system is tuned to a BBS or HD-SAT
signal, will give the signal strength between 0 and 100.
CHECKSUM - 3 checksums will be displayed.
I: internal ARM ROM checksum
H: checksum on the 2 highest megabytes of flash
L: checksum on the 2 lowest megabytes of flash
EEPROM - The AVDEC and Tuner EEPROM are checked.
SYSTEM RAM - The transport, external and cache RAM are
tested.
VIDEO DRAM - The video DRAM is tested.
MODEM - Will call the phone number entered in the Modem
Number Menu. A complete set of modem test are performed.
PHONELINE LEVEL - Will display the voltage measured on
the phone line.
DIAL TONE - Checks dail tone. Will display whether the
dialing method is DTMF or Pulse.
Press the Menu/OK on FPA or OK button on Remote to begin
Service Test. The Service Test screen will test the system and
place the results in the right-hand side of the screen.
AV&TL - AV (Audio/Video) and TL (Tuner Link) are
identifiers stored in the EEPROMS.
ROM - The first 4 charaters are the "software model
number". The next set of charaters will be the
software version. If there is a valid patch, then its ID is
displayed as the next 4 charaters. "M" is displayed if
Macrovision is enabled. "C" is displayed if Colorburst is
enabled.
Example: 028a A04.26 B03.07 MC00
software software patch ID macrovision
model number version colorburst
enable
CB HISTORY - Indicating the diagnostics for the last 5
attempted calls.
The "Information" screen will display AV&TL, ROM,
VERIFIER/CAM and CAM ID test results. Press the Menu/
OK on FPA or OK button on remote to run these tests. The
"Odomter" screen will display the Activation Date a
DIRECTV signal is acquired for the first time. The Service
Counter indicates the number of hours the system has been
under power (not just turned on). The "Phone Prefix" screen
allows you to enter a 1-digit to access an outside line and also
a Call Waiting disable code as well. The "Moden Number"
screen will allow a 11-digit phone number to be used during
the System Test.
VERIFIER/CAM - Number comes from the verifier software.
The first number is the software version. The next
number is the CAM version.
Page 3-6
DTV307
ALIGNMENT PROCEDURES (Continued)
DTV307 Color Temperature Alignment
Color temperature alignment for the DTV307 projection
instrument becomes complex. AKB is not utilized in this
instrument and color temperature must be setup for both user
selectable color temperature modes, "Normal" and "Warm".
Color temperature is actually setup for only one user mode,
then the remainder of the settings are calculated and placed
into the proper EEPROM locations. Proper color temperature
setup is dependant upon screen control setup. This adjustment
is done only once and used as a "reference" for the remaining
adjustments.
The order of adjustment is important. The proper order is:
1. Screen Control Setup
2. 2.14H "Video" Mode, "Normal" Temperature.
3. 2.14H, "Video" Mode, "Warm" Temperature.
Screen Control Setup
If screen control setup is done properly, the original color
temperature settings will probably be acceptable.
NOTE: AKB will remain "OFF" (0) for all operating
conditions of the DTV307 including all alignment
procedures. AKB is not used in the DTV307
instrument at this time.
PRESETS:
To begin, set the instrument to receive a "Comp" input on the
Component Video Input (Y, PR, PB) on the rear jack panel
using a clean average video signal. Preheat the instrument for
at least 20 minutes with an active video display.
In the consumer menu, under Picture Quality, set the
Picture Presets to "Normal Lighting". Then using the
Picture Controls, set Contrast to "maximum" and Color to
"minimum". Set Color Warmth to "Normal".
5. Set Video Mode Light Output (P24) to "V:64".
6. Set Blue Drive (P23) to V:64.
7. Set Red Drive (P22) to V:64.
8. Set Video Mode Cutoff (P21) to V:64.
9. Set Blue Cutoff (P:20) to V:127.
10. Set Green Cutoff (P:19) to V:127.
11. Set Red Cutoff (P:18) to V:127.
12. Making certain the 0 IRE Flat Field pattern (TP2) is still
displayed, observe the LED's located on the kine boards
on the neck of the CRT's. Adjust the Video Mode Cutoff
(P21) until any LED illuminates. Continue increasing
P:21 until the second of the three LED's illuminates. It
does not matter at this point if the first LED goes dim.
13. Now adjust the Red, Blue or Green cutoff control for the
LED THAT HAS NOT YET ILLUMINATED until
that LED also lights.
NOTE: If the cutoff control runs out of range, increase the
Video Mode Cutoff (P:21) until the final LED lights.
14. Now decrease the two remaining cutoff controls until the
respective LED's are just lit.
15. Continue fine adjustment of the Red, Green and Blue
cutoff controls until all three LED's are full on.
16. If a colorimeter is available adjust the screen controls for
x=.300, y=.310 and Y=1.0 +0.25. If not, increase the
screen controls to provide a low level gray pattern. A 10
Bar Gray Scale or similar pattern may be used to provide
a known gray pattern. The important point is when the
adjustment is complete a very low level uniform gray
pattern should be visible when the flat field gray pattern
(TP2) is placed on the screen.
DO NOT ADJUST THE SCREEN CONTROLS AGAIN
AFTER THIS STEP!!!
In the consumer menu under Screen, set the Menu
Background Color to "Transparent".
Four test patterns, will be required for the procedure. TP1
is a 12 IRE 50% display window for setting the screen
controls, lowlights. TP2 is a 0 IRE flat field for setting cathode
cutoffs. TP3 is a 100 IRE flat field for setting highlights. TP4
is a 100 IRE 50% Window for setting light output.
To Adjust the Screen Control:
1. Apply TP1 to the Component Video Input (Y, PR, PB).
2. Make certain the preheat and preset conditions have been
met.
3. Enter the serviceman menu using the front panel buttons
by pressing simultaneously "TV/DIRECTV" and
"CHANNEL DOWN" . Use "VOL UP" to place the "V:"
value to "76". When a parameter is specified use "CH
UP" or "CH DN" to change to the correct parameter
number, then use "VOL UP" or "VOL DN" to change the
value of the paramter.
4. Set all three screen controls on the focus/screen assembly
to minimum (full CCW).
17. Exit the serviceman menu by pressing "INFO" on the
remote control. This stores the new values to the
EEPROM and completes screen control setup.
If a colorimeter is not available color temperature setup
and screen control adjustment should end here. If a
colorimeter is available continue to the next section.
To Adjust 2.14H "Video" Mode "Normal" Color
Temperature:
1. Apply TP1 to the Component Video Input (Y, PR, PB)
and adjust the instrument for normal reception.
2. Make certain the preheat and preset conditions have
been met. In the consumer menu, under Picture Quality,
set the Picture Presets to "Normal Lighting". Then
using the Picture Controls, set Contrast to "maximum"
and Color to "minimum". Set Color Warmth to
"Normal".
Page 3-7
DTV307
do
atte
do
atte
ALIGNMENT PROCEDURES (Continued)
50% 12 IRE
w P
Win
rn
50% 100 IRE
w P
Win
rn
Window Patterns for Color Temperature Setup
Page 3-8
DTV307
ALIGNMENT PROCEDURES (Continued)
3 . Enter the serviceman menu using the front panel buttons
by pressing simultaneously the "TV/DIRECTV" and
"CHANNEL DOWN". Use "VOL UP" to place the "V:"
value to "76". When a parameter is specified use "CH
UP" or "CH DN" to change to the correct parameter
number, then use "VOL UP" or "VOL DN" to change the
value of the parameter.
4. Set the RGB Output Mode (P:41) to V:2. This changes
the screen output to green only.
5. Using the colorimeter, adjust Video Mode Cutoff (P:21)
for Y=0.420.
6. Change the video test pattern to TP3 (100 IRE Flat Field).
Measure the light output with the colorimeter and record
as LO#1_____ .
7. Change the video test pattern to TP4 (100 IRE Window).
Measure the light output with the colorimeter and adjust
the Video Mode Light Output (P:24) to obtain a reading
1.78 times that of LO#1. Record it as LO#2______ .
8. Change the video pattern back to TP1 and repeat step 57 if necessary.
9. To return all three colors, set RGB Output Mode (P:41) to
V:0.
10. Change the video test pattern to TP1 (12 IRE Window)
and adjust the Red, Green and Blue Cutoffs (P:18, P:19
and P:20) and Video Mode Cutoff (P:21) using the
colorimeter for x=0.300, y=0.310, Y=0.600.
11 . Change the video test pattern to TP3 (100 IRE Flat Field).
Set highlight temperature using the Red and Blue Drives
(P:22 and P:23) for x=0.300, y=0.310.
12. Repeat steps 10 and 11 as needed for accuracy.
13 . Record the values for P:18, P:19, P:20, P:21, P22, P23 and
P24. These values will be transfered to the same
parameters in the "Warm Color Temp Mode" to be used
as a starting point.
14. Exit the serviceman menu by pressing "INFO" on the
remote control.
15. Enter the customer menu, select "Color Warmth".
Change from "Normal" to "Warm" then back to
"Normal" to set the correct cutoff values.
To Adjust 2.14H "Video" Mode "Warm" Temperature
Light Output:
1. Set the instrument to receive a "Comp" input on the
Component Video Input (Y, PR, PB) on the rear jack
panel using a clean average video signal. Preheat the
instrument for at least 20 minutes with an active video
display.
2. In the consumer menu, under Picture Quality, set
Contrast to "maximum", "Color" to "minimum", Color
Warmth to "Warm".
3. In the consumer menu under Screen, set the Menu
Background Color to "Transparent".
4 . Enter the serviceman menu using the front panel buttons
by pressing simultaneously the "TV/DIRECTV" and
"CHANNEL DOWN". Use "VOL UP" to place the "V:"
value to "76". When a parameter is specified use "CH
UP" or "CH DN" to change to the correct parameter
number, then use "VOL UP" or "VOL DN" to change the
value of the parameter.
5. Set P18, P19, P20, P21, P22, P23 and P23 to the value
recorded in the previous 2.14H "Normal" setup to be
used as a starting point.
6. Change the video test pattern to TP1 (12 IRE Window)
and adjust the Red, Green and Blue Cutoffs (P:18, P:19
and P:20) and Video Mode Cutoff (P:21) using the
colorimeter for x=0.313, y=0.329, Y=0.600.
7. Change the video test pattern to TP3 (100 IRE Flat Field).
Set highlight temperature using the Red and Blue Drives
(P:22 and P:23) for x=0.313, y=0.329.
8. Repeat steps 6 and 7 as needed for accuracy
9. Exit the serviceman menu by pressing "INFO" on the
remote control.
Conclusion
The purpose of screen control alignment is to match the
electronic video signal to the CRT electrical characteristics.
In other words, if the video signal requires beam current to
stop, the CRT must know that value. Screen control setup is
an exact adjustment.
On the other hand, color temperature can be perceived
differently depending upon room lighting and environment,
original program material, electrical adjustment of the video
processing and control circuits and finally, the viewer. What
looks red to a technician, may look purple or orange or any
other color to another viewer. The technician should strive to
provide a "trained" eye by knowing what proper color
tracking is. "Color Tracking" itself is a misnomer. Color
temperature alignment is actually striving for a uniform gray,
with no hint of color tinting, as the ideal for any light output
level of the CRT.
Page 3-9
DTV307
ALIGNMENT PROCEDURES (Continued)
Comb D/A Level - Composite (Parameter 32)
1. Apply a 100 IRE (white) signal to the AUX 1 input.
2. Select AUX 1 for the main picture.
3. Connect a scope probe to the negative lead of C22323.
4. Adjust the Comb D/A value (Parameter 32) for 0.71
volts from black (blanking) to white.
Comb D/A Level - SVideo (Parameter 36)
1. Apply a 100 IRE (white) signal to the SVideo input.
2. Select SVideo for the main picture.
3. Connect a scope probe to the negative lead of C22323.
4. Adjust the Comb D/A value (Parameter 32) for 0.71
volts from black (blanking) to white.
PIP Contrast - Composite (Parameter 33)
1. Apply a color bar signal to the AUX 1 input.
2. Select AUX 1 for the main picture.
3. Turn on PIP and select AUX 1 for the PIP picture.
4. Adjust PIP Contrast (Parameter 33) for equal contrast
levels between the main picture and the PIP picture.
PIP Tint\Saturation - Composite (Parameters 34, 35)
1. Apply a color bar signal to the AUX 1 input.
2. Select AUX 1 for the main picture.
3. Turn on PIP and select AUX 1 for the PIP picture.
4. Adjust PIP Tint (Parameter 34) for equal tint between the
main picture and the PIP picture.
5. Adjust PIP Saturation (Parameter 35) for equal
saturation between the main picture and the PIP picture
(may affect tint slightly).
6. Repeat steps 4 and 5 until both the tint and saturation
level are the same for both pictures.
PIP Contrast - SVideo (Parameter 37)
1. Apply a color bar signal to the SVideo input.
2. Select SVideo for the main picture.
3. Turn on PIP and select SVideo for the PIP picture.
4. Adjust PIP Contrast (Parameter 37) for equal contrast
levels between the main picture and the PIP picture.
Geometry Adjustments
The Geometry alignments on this chassis are very critical
and must be performed using ChipperCheck®. Even though
some of the geometry alignments are available through the
front panel service menu, adjustment is not recommended.
Alignment in one mode will interact and affect the displays of
the other modes.
To perform geometry adjustments a template must be
placed on the screen. The grid divides the screen into 6.5
equal squares from right and left to center. It also divides the
screen into 5.5 squares from top and bottom to center.
If a template is not available, center screen may be
confirmed by placing two strings on the screen. One string is
placed on the diagonal from the top left corner to the bottom
right. The other is fixed from the top right corner to the bottom
left. The intersection of the two lines should be center screen.
The outer lines should be just at the frame. All other lines can
be measured from center screen and the frame. Chipper
Check will provide the measurements depending upon screen
size.
For the remainder of the adjustments the grid must be used
and the following order FOLLOWED EXACTLY!!!
P12: Do not adjust!
P6 is fixed at V:32.
P10 is fixed at V:3.
P8 is fixed at V:4.
P13 is set to V:32 for 2.14H. All other modes the center
horizontal line should intersect at the screen center.
P5 is adjusted such that the right border is just inside the
screen frame at point B.
P11 is adjusted to place the top border (horizontal line
intersecting point D) is at the upper screen edge.
P7 is set to obtain the straightest line between points D and E.
P9 is set for the straightest line between points D and E.
P11 is re-adjusted (if required) to place the top border
(horizontal line intersecting point D) is at the upper screen
edge.
P4 is adjusted after returning normal video to the screen for
horizontal centering.
C
D
PIP Tint\Saturation - SVideo (Parameters 38,39)
1. Apply a color bar signal to the SVideo input.
2. Select SVideo for the main picture.
3. Turn on PIP and select SVideo for the PIP picture.
4. Adjust PIP Tint (Parameter 33 for equal tint between the
main picture and the PIP picture.
5. Adjust PIP Saturation (Parameter 39) for equal
saturation between the main picture and the PIP picture
(may affect tint slightly).
6. Repeat steps 4 and 5 until both the tint and saturation
level are the same for both pictures.
Page 3-10
A
Figure 1 - Geometry Pattern
B
E
DTV307
ALIGNMENT PROCEDURES (Continued)
Yoke Centering Ring Adjustment
If Chipper Check is not available it is possible to replace a
single CRT and realign geometry by using the centering rings
on the CRT.
Using the convergence pattern available when in service menu
V:80, the pattern from the replacement CRT may be adjusted
to align with either of the two remaining CRT's using the
centering rings shown in Figure 2.
First make certain the replacement CRT is placed back in the
mounting as close as possible to the position of the original
CRT. At this point having the convergence pattern on screen
will assist in the mechanical mounting. Once the CRT
assembly is located fasten it securely.
Rotate Tabs Together
Spread Tabs Apart
Centering
SVM Y oke
Phosphor
Screen
Kine
Socket
Figure 2 - Centering Rings
Figure 3 - Centering Ring Tab Movement
Using the centering rings (Figure 3) and observing the
convergence pattern, rotate and move the pattern until the
replacement color overlays as close as possible to the two
colors not replaced. Moving the ring tabs together around the
neck of the CRT draws the raster in small circles. Spreading
the tabs apart moves the raster in more linear angles. The
closer the tabs are together, the less affect on the CRT beam
they have.
When the raster is as close as possible fix the magnets with
paint or nail polish to prevent further movement.
After fixing the magnets, if gross geometry errors are
apparent, geometry alignment is indicated. If the raster is
close use the "Auto-convergence" feature provided in the
consumer menu to re-align convergence. This should correct
most minor geometry problems. Follow auto-convergence
with the consumer red and blue centering adjustments, then
evaluate the raster again.
In most cases convergence will now be acceptable. If only
slight convergence errors are noted the technician should
enter the manual digital convergence menu at V:80 and begin
"touch-up" of the screen.
If gross geometry errors are still apparent re-evaluate whether
the errors are noticable on the replacement CRT or whether
they are global, affecting all three c CRT's. If the errors affect
all three CRT's a full geometry alignment is indicated. If the
errors only affect one CRT, particulary the replacement,
return to the mechanical placement and centering ring
adjustments and begin those procedures again.
Page 3-11
DTV307
ALIGNMENT PROCEDURES (Continued)
Digital Convergence
There are four security locations associated with digital
convergence. Their exact functions will be explained later.
They are:
V: 76; The main service alignment location.
Contains the geometry alignments associated with
convergence.
V: 80; The main digital convergence location.
V: 82; PTV sensor positioning.
V: 83; Restore factory Digital Convergence
values.
V: 84; Save current alignments.
When the chassis is in service mode and digital convergence
is active (V:80) the following remote control functions are
enabled:
INFO; Toggles the convergence mode off after
alignments are completed
CH+/CH-; Adjusts the selected alignment point up
or down.
VOL+/VOL-; Adjusts the selected alignment point
right or left.
Cursor Arrow Buttons; Moves the cursor in the
appropriate direction.
SKIP; Toggles the convergence mode through the
following four states.
Red to Green: Allows adjustment of red
convergence using the green pattern as a
template.
Blue to Green: Allows adjustment of blue
convergence using the green pattern as a
template.
All: Allows adjustment of the green
convergence. Provides a white convergence
pattern allowing comparison of the pattern for
more accurate results.
Green: Allows adjustment of the green
convergence. This should be used only with a
mylar template or strings placed on the front
screen.
Figure 4 - Main Convergence Screen with Cursor at Center
Convergence Pattern
The convergence pattern displayed when in the digital
convergence mode (V:80) appears as in Figure 4. Shown is
the cursor at center screen. This is how the convergence
pattern appears when the technician initially enters the digital
convergence alignment mode.
CAUTION: DO NOT PRESS THE "OFF" BUTTON. THIS
WOULD TURN OFF THE SET WITHOUT SAVING THE
CONVERGENCE ADJUSTMENTS.
All other buttons are ignored by System Control and the
Digital Convergence microprocessor during convergence
alignment.
After placing the instrument in service mode, use either the
remote control or the front panel button VOL UP to advance
the right side screen number (V:) to 80. Then push CH UP.
This places the instrument in digital convergence mode.
Page 3-12
DTV307
ALIGNMENT PROCEDURES (Continued)
Convergence Mode
During digital convergence mode, the display will blank
incoming video allowing only the digital convergence
crosshatch pattern with the cursor at the center location. The
initial adjustment is red. Green is fixed. Red and blue will be
aligned to green.
The volume and channel buttons will provide adjustment of
the selected cursor location up, down, left and right in single
steps. The cursor position is indicated by a crosshair. The
intersection of the highlighted crosshair is the alignment
currently being adjusted. Note only a portion of the crosshair
will be seen when it is positioned to adjust the off-screen
points along the picture edges. Use the small line segments
that extend to the picture edge to adjust these points.
NOTE: In the extreme diagonal positions, the
cursor is invisible but the point is still adjustable. Do
not adjust these off-screen corner points.
For best results, adjust the pattern beginning at the upper
left of the screen. Then continue the adjustments from left to
right and top to bottom as if reading a book.
The four navigation "MOVE" buttons adjust the movement
of the selected color at the cursor point. They will move the
alignment point for the selected color up, down, right or left.
Adjust so that it is centered on green with minimum fringing
on either side.
The "SKIP” button will toggle the display through
4 states:
1.
Yellow crosshatch, Yellow cursor, Red
adjustment, no other OSD or video.
2. Cyan crosshatch, Cyan cursor, Blue adjustment,
no other OSD or video.
3. White crosshatch, White cursor, no adjustment
available. Used to observe convergence results.
4. Green crosshatch, Green Cursor.
The PWR button returns the receiver to normal operation,
however the adjustments are not stored to EEPROM. More on
the actual storing of data to the digital convergence EEPROM
later.
As previously discussed, there are also four service menu
locations associated with digital convergence. They are:
V: 80; The main digital convergence
location.
V: 82; PTV sensor positioning.
V: 83; Restore factory Digital Convergence
values.
V: 84; Save current alignments.
V:80 is the main digital convergence menu. It contains an
"all-points" adjustment procedure very much like the
CTC195. When convergence alignments are complete, the
technician exits this menu by pressing "On/Off" on the remote
control or "Power" on the front panel. Convergence
alignments for the selected scan mode are stored in the current
mode EEPROM at this point and will be used until they are
changed during the next menu V:80 alignment procedure or
the consumer accesses the "Auto-Convergence" procedure.
In that case, the original factory alignment data will be placed
back into the EEPROM and the screen aligned to the faulty
data.
To prevent this, once alignments are complete for the
selected mode, the service menu must be entered again, this
time V:84 will be selected. At V:84, press CH UP. This
transfers the new alignment data for the selected deflection
mode to the factory EEPROM. Then the service menu is
decremented to V:82 and CH UP is again pressed. This starts
a routine to allow the optical sensors located on the screen
frame to "memorize" the new alignment data. It looks similar
to the consumer "Auto-convergence" procedure. Once the
routine is completed "Auto-convergence" will function
correctly, returning the screen to the convergence setup by the
technician. This new data becomes the "factory default" data
from this point forward, only changing if a new set of
alignments is placed into the EEPROM using the same
procedure.
Menu V:83 performs the same convergence routine as
selecting "Auto-convergence" from the consumer menu.
Digital Convergence Alignment Overview
There are four convergence modes in the DTV307
corresponding to the four deflection (scan) modes. Each
requires complete convergence alignment and stores the
alignment points in separate EEPROMS. There is also
another EEPROM containing convergence data installed at
the time of manufacture. It is always available to allow a
"starting" point in cases where catastrophic failure of
convergence data has occured. This EEPROM is larger than
the others and contains reference data for all four scan modes.
Page 3-13
BLOCK DIAGRAM
SCLM
SDAM
SCLS
SDAI
SDAO
ADS0
OSCL
GRES
ECLK
FILT
FLT2
SYNH
SYNV
REST
TEST
I2C
Master
I2C
Slave
Oscillator
PLL
SYS_CLK
Filter
Reset
Controller
Digicon III
RAM
RAM
Controller
Bus
Controller
Horizontal
Timebase
Timebase
Vertical
Video
DACs
Interpolation
Registers
D0...E2
Registers
E3...EE
Video Pattern
Generator
RGB
Registers
Timing
Gain Range
Control
Electrical
Loop
OPT
Port
H
dig.
Filter
V
dig.
Filter
Convergence
DACs
Focus
Processor
I/O Ports
R
G
B
R
G
B
Bandgap
Focus
DAC
DARH
DNRH
DAGH
DNGH
DABH
DNBH
DARV
DNRV
DAGV
DNGV
DABV
DNBV
REFN
REFC
POUT
DACF
DNCF
MLIN
VIDB
VIDR
VIDG
OPTI
VBLK
OPTT
PORA
PORB
PORC
OGAH
TBU0
TBU1
TBU2
TBU3
TBU4
TBU5
TBU6
OGAV
TBU7
DTV307
CIRCUIT OVERVIEW
AC IN
Three line chokes in series and capacitors across the
outputs are used to provide Line Conducted Interference
(LCI) suppression to the AC line. A full wave bridge is
connected to the 60Hz ac line to provide Raw B+ to both
the standby Zero Voltage Switching (ZVS) circuit and the
main high power isolat ing regulator.
A provision for a Negative Temperature Coefficient
Resistor (NTC) RT14202 may be used as a surge current
resistor to c ontrol inrush curre nt through the diod es as the
main electrolytic charges initially to minimize power and
temperature.
Grounding of the 3-wire line cord is to the metal
mechanical structure to which the main spark gap and
audio/video grounds are connected.
Main Run Power Supply
Main Run Power Supply Operation
The main run power supply circuit operates in the Zero
Voltage Switching (ZVS) mode to minimize radiated
noise and to improve efficiency.
A high power output, single switch power supply requires
a switching device that has a high curre nt rating and high
breakdown voltage. The most cost-effective type of
device for this application is a bipolar switching transistor,
but bipolar transistor require a significant amount of base
current drive in the forward direction, and even higher
level of current during turn-off to ensure fast switching.
A simple proportional drive circuit that also provides a
self-oscillating capability has been developed for the
DT30X family. Proportional drive is advantageous
because it provides a relatively constant ratio of base
current to collector current. This constant ratio prevents
the switching transistor base from being overdriven in the
forward direction during low current operation, thus
improving the switching speeds. Proportional drive also
provides increased base drive when high peak current is
required from the switching transistor to ensure proper
saturation to minimize power dissipation. This circuit
operates in the forward mode because of the high power
output requirements, providing energy to the secondary
windings during the main switch cond uction interval. I n
this implementation the primary winding of T14101,
provides the means for the energy stored in the resonant
inductor to be transferred to the output while the switching
transistor is on.
Page 5-1
DTV307
CIRCUIT OVERVIEW
A high current latch provides a low impedance path for
reverse base current to flow during turn-off. The latch is
made up of Q14101 and Q14103 a PNP/NPN transistor
pair. A negative bias on the base of the switching
transistor, Q14100, is provided by the drive transformer, a
series Zener diode, CR14105, and bypass capacitor,
C14103, to improve reliability and switching speeds.
Oscillation is initiated by current flowing from a high
value resistor R14103 connected to the Raw B+. It causes
a small amount of base current to flow in the main power
switch Q14100. A drive transformer T14101 is connected
as a current transformer and causes current to flow in the
secondary winding in response to the current flow in the
primary winding. The ratio of primary current to
secondary current is determined by the turns ratio of the
drive transformer, about 7 to 1. Since additional current
begins to flow in the base of the switching transistor from
the secondary of T14101, additional current will flow in
the primary and a regenerative effect will take place
causing the system to self oscillate. The expected range
of switching frequency is 80kHz to 120 kHz.
Switch Mode transistor current is sensed by an emitter
resistor, R14100; the developed voltage is fed to the
NPN/PNP latch. When the voltage across R14100
increases the base of Q14103 becomes sufficiently
positive to cause it to turn-on. Current flowing in Q14103
causes Q14101 to turn-on diverting base current away
from the Q14100 and latching Q14103. CR14105 and
C14103 provide a negative voltage feedback to the base
of Q14100 to improve the turn off characteristics of the
main power switch.
a current path of the forward drive current and limits the
voltage to which C14104 can charge. A negative base
bias voltage is coupled to Q14100 through C14104 to
Q14100 when it is in the off state. Diode CR14117 and
C14121 bias and rectify and filter the negative voltage
developed from the drive transformer, T14101, to provide
a negative supply voltage for the control circuit.
A feedback signal from an error amplifier that senses the
output voltage of the supply drives an opto-coupler with a
variable current. The +76V supply is sensed via a resistor
divider and fed to the reference IC U14101. As the output
voltage increases above the threshold set by the error
amplifier, the current through the diode portion of the
opto-coupler increases causing increasing current to flow
in the transistor portion. This increased current flow
causes the voltage across C14112 to drop which in turn
lowers the threshold at which Q14103 will begin to
conduct, lowers the peak current in the switching device,
and reduces the output voltage of the system until
equilibrium is established.
Overcurrent Protection
When an overload appears, the current through (and the
voltage across) the sense resistors approaches a sawtooth
shape with nearly equal positive and negative amplitudes.
The negative-going portion of this voltage is passed by
CR14122 and lowers the voltage on the emitter of
Q14103 that in turn lowers the maximum peak current that
can flow through the transistor.
Standby Power Operation
Diode CR14108 and resistor R14117 shunt some of the
reverse base current to the low impedance of the current
sense resistor. This shunting effect prevents the
overstressing the base of Q14103.
Q14102 and Q14103 remain latched until the current
flowing through the pair drops below the latching
threshold. The negative voltage produced by T14101
keeps the main switch mode transistor from conducting
until the resonant action of the resonating inductor and the
resonant capacitor, C14113, causes the voltage to reverse.
As the voltage at the base of Q14100 rises, current begins
to flow and the next cycle begins.
When Q14100 turns off, the collector voltage begins to
rise but the voltage change is limited by the resonance
effect produced by L14103 and C14113. Because
Q14100 turns off very rapidly, very little power is
dissipated since the collector voltage remains low during
the turn-off interval. When the collector voltage of
Q14100 resonates toward ground, the collector-base
junction conducts and diode CR14128 provides a path for
the resonant current returning to the Raw B+ supply after
the resonant cycle is complete. Diode CR14115 provides
The standby power supply uses a ZVS circuit similar to
the main run circuitry. It uses a flyback topology rather
than the forward mode of the main power supply. A
MOSFET, Q14601, serves as the switching device with
the energy storage components the primary inductance of
T14600 and the resonating capacitor, C14605.
+5VFB is sampled and regulated directly via the reference
IC U14603 and opto-coupler, U14601. A transistor
switch Q14604 is enabled by the +12v run in order to
shed load in the standby mode.
An isolated supply (+8V_USB) provides the source for
the USB 5v regulator that is located on the I/O board.
Provisions ha ve been made for powering a tuner with the
+15vs, +33vs and -12vs. The +33vs is switched on by the
+12vr.
On sets supporting GemStar99, a 9VS standby source is
provided from +15VS via a dropping resistor to form an
unregulated +12VS. This supply is fed to a switched +9V
Page 5-2
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