The DVD Recorder that has been incorporated in the LCD TV High Definition Combo unit is basically the same as that of the DMR-E65.The equipment used for servicing the DMR-E65 is same as the one used for servicing this model’s DVD-RAM Drive .The only difference is that the DVD Recorder (DMR) has been downsized to a physically smaller drive.
The LCD AI (Artificial Intelligence) technology incorporated within this model is very similar to that covered in previous LCD models. The Pixel Control IC, in conjunction with the Main Microcontroller IC, located on the DG Board, is responsible for controlling the backlighting and the active matrix display addressing.
System
Control Block
Main Power switch signal is
derived from the power on switch, which is located on the K board. The Main
Micro (TV Microcontroller), located on the DG board, sees this as a “key scan” input signal and issues a TV ON and AC_On to the control circuitry
within the Primary and secondary power supply.DVD Power switch signal is derived from the DVD operation switch, located on
the DVD OP board. This signal is responsible for initiating the power on
sequence for the DVD operation. The Main Micro sees this as a “key scan” input signal.
Panel ON signal appears on pin 28 of the
DG board connector DG2. This is equivalent to an on/off switch for the LCD
Panel.
Backlight ON /OFF (B/L On/Off) signal
provides the enable for the DC to AC backlight inverter power supply which is
incorporated within the LCD Panel.
OSD Timing Compensator synchronizes the
OSD with the incoming video.
System Shutdown
The Main Micro on the DG board is responsible for monitoring the various
shutdown conditions. The Main Micro monitors the SOS and main voltage (Zero X
Detect) detection signals via the DG2 connector.
LED Functions
The Time Warp Led indicates that the DVD is recording at twice the normal record mode (operator’s choice)
The SD LED indicates that the SD card is being accessed either for a read or a write operation
The DVD LED indicates that the DVD unit is being accessed either for a read or a write operation
* TV Data In/Out are DVD control lines used for playback and record.
* DVD Play switches the audio monitor output from all audio inputs to the DVD Output.
* Wake Up provides Serial data communication between the DVD Micro and Main Micro.
* Fan Control is accomplished through the use of a fan control circuit located on the DVD main circuit board. A PWM output signal from sub processor IC 7501 controls the speed of the fan, based on the internal ambient temperature of the unit .
A
Board (TC-22LR30)
The
Video Switch IC3101 is responsible for selectively switching all video inputs (Component,
Composite, S-Video and HDMI). The selected input is fed to the DG Board via the connector A1.
* The Audio Switch (IC3102) selects the desired audio input for processing by the
Sound Control (IC2301). The MTS (IC3103) performs stereo separation of the tuner’s multiplex signal and sends the output to the audio switch.* The TA tuner board on the TC-22LR30 provides the same functionality as the B tuner
board found on the TC26/32LX20. The output is connected to the A board via connector PA7.
The
HDMI interface, which resides on the DV board, processes and converts the digital
video and audio signals to analog and outputs them to the DG board via the video switch.
H Board (TC-26/32LX20)
The H Board on models TC-26/32LX20 is comprised of an S - Video and Composite video input connection, two Component video inputs, a DVI audio input and an Audio output connection. This board has been merged onto the A board of the TC-22LR30 Combo unit.
K board (TC-22LR30, TC-26/32LX20)
The K board contains the TV ON/Off, Volume, and Channel select buttons, and an additional S-Video and Composite video input connector and headphone jack. It connects to the A board via connector K3.
Power
Supply (TC-22LR30)
The power source for all models is comprised of a Primary and Secondary power supply.
The P Board is responsible for generating the primary source voltage used to supply power to the secondary power supply, located on the AP board. It also
supplies the voltage that feeds the backlighting circuitry, which is
incorporated on the LCD panel.Newer models such as the TC-22LR30 use a 15 volts source that feeds this
circuit (DC to AC inverter). However, the TC-26/32LX20 and TC-32LH models use
120 volts as input for the backlight circuitry of their LCD panel.
The
AP Board is responsible for supplying all secondary voltages required for operation.
Modifications were made on the TC26/32LX20 models AP board to accommodate the voltages required to power up the DVD RAM, which was basically added
to the TC-26/32LX20 to make it into a combo unit (TC-22LR30).
P
Board - Primary Power
The Primary power supply is responsible for generating the following:
1. The standby power supply
2. The primary source voltage (14volts) for the secondary power supply.
3. Backlighting voltage (15 Volts) for the TC-22LR30
STANDBY POWER Circuit
The incoming AC voltage passes through the inrush current resistor R7001 and enters the rectifier circuit consisting of D7015, D7022, D7023, and D7024 for conversion to DC. The output is then applied to IC7005, a 7volt regulator. The 7volt output of the regulator is sent to the AP board for conversion into 3.3V. This 3.3V is provided to the DG board via pin 44 of the connector PAP2 to serve as standby voltage for the system control circuit.
14V POWER SUPPLY
When a power up command is sent by the system control IC (Main Micro IC1106 on the DG board), the AC_ON pin 47(connector PAP4 pin 13) sends a high to transistors Q7002 and Q7003 to activate the power relay RL7001. AC passes through the relay and enters the bridge rectifier consisting of D7005, D7007, D7008, and D7011.
The diodes convert the AC voltage into DC, which is then applied to pin 3 of IC7003 via the transformer T7001. The voltage on pin 3 of this IC causes it to oscillate and output a PWM pulse to drive the transformer T7001. As a result, energy is built and released from the transformer.
The AC output at pin 11 and 14 of the transformer is rectified into 14 volts to serve as the primary source for all other voltages. After the power supply starts running, the Run Supply for IC7003 is supplied by diode D7033 connected to pin 8 of a secondary winding of T7001. AC voltage from pin 8 of the transformer is also rectified by D7034 and applied to a switching control (regulator) circuit consisting of Q7005. Output of the switching control IC is tied to pin 4 of IC7003 where it is monitored for over voltage conditions. Voltage regulation is achieved via the 14V Error Detection circuit, which consists of IC7006 and IC7008. The output of IC7006 is connected to pin 1 of IC7003, the same input as the Run Supply.
15V
POWER SUPPLY
This circuit generates +15Vdc used on the AP board. This voltage is also used
to power up the DC to AC converter for the backlight of the LCD Panel. The
switched 14Volts (sw+14V., which is generated when the unit is powered up), in
conjunction with the MAIN_ON_ACT (signal (H): approx.3.0V), allows Q7001 to
turn on and activate the Relay (RL7002). The rest of the operation is exactly
the same as that of the 14 Volts power supply.
AP
Board - Secondary Power
The Secondary power supply is responsible for producing the various voltages
that are required to power the DG board, the A board, the DVD unit and the LCD
Panel VCC.
These voltages appear on connectors PAP2, PAP5 and PAP6.
* The 15V supplied from the P Board Connector PAP4 is converted to the MAIN
12V, which supplies this voltage to the Audio AMP Circuitry located on the A
board.
* When a MAIN_ON signal (3.3V) from Pin 69 of Microcontroller (IC1106) is issued
to this board to turn off the Main power (MAIN 12V, 9V, 3.3V, 2.5V), the MAIN_ON
signal is converted to MAIN_ON_ACT to turn off Regulators (IC801, IC806, Q801,
Q803) which in turn terminates the Main power.
During normal operation the MAIN_ON_ACT signal (L) provides an enable to
regulators IC801, IC806, Q801, and Q803, which provides for the appropriate
output of the Main power. Over Current Protection Shutdown Circuits
There are several protection (shutdown) circuits that monitor the voltage
sources for over voltage and over current conditions. They prevent the
occurrence of catastrophic failures by shutting down the unit. The circuit below is used to prevent
catastrophic failures if the Sub_5V, Sub_9V, Main_9V, or DR_12V becomes
shorted. These are voltage loss detection circuits that have the same method of operation. Let us
analyze the main 9V source as an example.
The circuit consists of a diode whose cathode is connected to a positive B+
source.
Under normal conditions, the diode is reverse biased, which keeps the base of
Q832 high. However, if there is a short or excessive load on the Main 9V line
that is being monitored, the diode conducts, creating a current path for the
base bias of Q832. The transistor turns on and allows 3.3V to output at the
collector. This voltage is then provided to the base of transistor Q829 via the
diode D874, forcing its collector to go low. This low enters the SOS input of
the MPU via pin 42 of the connector PAP2/DG2.
The MPU reacts by having AC ON (H) go Low. This, as you may recall, is supplied
to the SUB POWER CIRCUIT of the P board to shut off the SUB Power (14V) and the
MAIN Power (15V) voltage sources.
SOS
Shutdown
14-Volt
Power Down Detect Circuit
The Zero X Detect circuit monitors the presence of the 14 volts source of the
main pin power supply (P board) and the Sub_5V of the AP board. Under normal
operation, 5 of the connector DG2 supplies a High to pin 61 of the MPU, IC1106. If, for
any reason the Sub_5V or 14 Volts lines drop or disappear, pin 5 of the
connector DG2 becomes low level to trigger a complete shut down of the unit.
Over
Voltage Protection _ AC Shutdown Latch Circuit
This protection circuit is responsible for forcing the AC _On voltage to a low
if any of these protected voltages mentioned in the next paragraph become
excessive. The AC _On voltage is used to activate the relay RL7001, which is
used to power up the unit.
Transistor
Q822 monitors the Sub_+3.3V, Sub_9V, Main_11.2V, DVD_5.9V, and DVD_1.8V; Drive
12V, Sub_5V, and Sub_9V lines. If any of these supply lines increase in
voltage, transistor Q822 goes into conduction causing its collector to go low.
As a result, Q823 conducts causing the AC _On voltage to drop. Transistor Q822
and Q82 form a latch that keeps the unit from being turned back on until it is
unplugged from the AC outlet and plugged in again.
Power Supply (TC-26/32LX20)
The power source for all models is comprised of a Primary and Secondary power supply. The P Board is responsible for generating the primary source voltage used to supply power to the secondary power supply, located on the AP board. It also supplies the voltage that feeds the backlighting circuitry, which is incorporated on the LCD panel. Newer models such as the TC-22LR30 use a 15volt source that feeds this circuit (DC to AC inverter). However, the TC-26/32LX20 and TC-32LH models use 120 volts as input to this circuit.
P board (TC-32LH, TC-26/32LX20) - Primary Power
The Primary power supply is responsible for generating the following:
* The primary source voltage (24 volts) for the secondary power supply The 7-volt standby voltage for the system control circuit
* Backlighting voltage 120 Volts for the TC-32LH, TC-26/32LX20
Standby Power Supply
The standby power supply provides the necessary DC voltage to the system control Microprocessor, the Reset circuit and the EEPROM. A.C. voltage is supplied to the Full Wave rectifier (D7025, D7026, D7031, D7030), through the Line Filter and Transformer T7004. The 7volts standby voltage produced by the rectifier is present as long as the unit is plugged in.
The 7volts output passes through the AP board and enters the DG board where it is regulated to 3.3V and fed to the system control circuit. Although the unit is plugged into the wall outlet, the main power switch located on the front face of the unit must be in the ON position for the unit to enter and remain in the standby mode.
Primary
Power Supply
When the system control circuit obtains a power up command from the operator,
the AC_ON pin of the MPU, IC1105, outputs a high to the relay control circuits
Q7011, Q7012, Q7015 & Q7016 to activate the relay RL7001. The AC voltage enters
D7002 for rectification into 24 volts DC where it activates the relay control
circuits Q7013 and Q7014 to activate relay RL7002. The DC level is then boosted
to 380Vdc by the Power Factor Control (PFC) circuit, IC7002. The power factor
control circuit is made up of an oscillator used to control the charge and
discharge time of the transformer T7001. Start up voltage for the circuit is
obtained at the output of the D7002.
As
the PWM pulses are output from IC7002, the transistors Q7003 and Q7004 are switched
ON/OFF to allow the charge and discharge of the transformer T7001. The charge of T7001 is added to the rectified voltage of D7002 to create 380V.
IC7002 also outputs a PWM output that turns the transistor Q7007 on and off to
control the charge and discharge time of the transformer T secondary output of
the transformer is rectified to 24Vdc and supplies the AP board. The diode D7017 rectifies the AC output of
one of the secondary windings of the transformer T7002 to serve as Run supply for
IC7002. Power On Operation of the DC-to- DC converter
The P board contains the drive voltage oscillator circuit that develops the 121
volts needed to drive the LCD backlight. Operation begins with the discharge of
transformer T7002. The diode D7018 rectifies the AC voltage from the secondary
of the transformer.
Approximately 30.1Vdc from the diode passes through the photo-coupler IC7005
and enters pin 6 of IC7001 to begin the oscillation. The pulses that are oscillator
enter the transformer T7004, causing it to build a magnetic field. The output
of the output at pin 1 of the the transformer is rectified into 121Vdc and provided
to the LCD panel via the connector P4. When the rectified output of the
transformer reaches 90Vdc, the diodes D7043, D7044, D7045, and D7046 go into
conduction, turning on transistor Q7010 and thereby, turning off IC7005. This
eliminates the start up voltage of IC7001. The oscillator continues to operate
using the run supply created by a secondary of the transformer T7004 and the
diode D7014.
Power
Off Operation of the DC-to-DC converter
When the unit is turned off, the 120V_Stop command is provided at pin 2 of the connector
P1/AP10. This causes the transistors Q7008 and Q7009 to turn on and stop the conduction of IC7005 and IC7006.
The 120V_Stop line is designed to stop the operation of the backlight DC-to-DC converter
if there is a drop or an increase in the 24 volts supply to the AP board. Pin 2 of the connector P1/AP10 inputs a High to the P board causing the transistors
Q7008 and Q7009 to turn on. This causes IC7006 to immediately turn on and short
pins 6 and 7 of IC7001. This action stops the oscillation of IC7001. To keep
the oscillation of the IC from starting again, the DC supply is grounded
through Q7008.
Protection
of the DC-to-DC converter
Over-current protection of the circuit is provided at pin 7 of the IC7001 from
the emitter output of Q7018.
Over-voltage protection of the primary is provided via the diode D7054. If the
rectified voltage of D7018 exceeds the operating voltage of IC7001, the diode
D7054 conducts and applies DC to the base of Q7019. The transistor Q7019 turns
on and causes Q7018 to turn off, effectively removing the feedback voltage to
pin 7 of IC7001. This action stops the operation of the oscillator.
AP
Board - Secondary Power Supply
The 14 volts derived from the primary power source on the P board enters the AP
power board, on the designated connector. The various voltages derived are used
to power the DG board, the Audio Control circuitry and the Tuner. If the 24volts
shuts down, a 120volt stop signal is generated which causes the unit to
shutdown.
Secondary
Voltages
The Main 3.3V, 2.5V and Sub 5V, are used to provide power to the DG board. IC80
provides a regulated 9 volts to IC808, which serves as the voltage source for
the tune Its output is 30 volts. The Main 9,10 and 12.4 volts supply the
secondary source vol to the rest of the unit.
Video Circuit
A Board
The A board serves as the entry point for all video signals that will be selectively processed by the DG board via Video Switch IC3101. The main microcontroller, which resides on the DG Board, is responsible for the selection of the designated video input through the use of the I2Bus select lines. Two composite, two S–Video inputs, a
Component, a single Tuner, an HDMI video, and a DVD video interface are selectively switched for video processing on the DG board. Connectors PA1 and DG1 serve as the signal access point.
Video read from the SD Card is processed by the DVD main unit (M8 and RD) where it enters the Video switch as DVD component Y/Pb/Pr video. Its output appears on connector PA1 as Main Y/Pb/Pr video where it enters the DG board on connector DG1 pins #37, 35, and 33.
* HDMI video from the DV board enters the video switch as HDMI Y/Pb/Pr and is also switched to the Main Y/Pb/Pr video input on the A Board
* The NTSC tuner inputs, and the S-video and composite inputs to the video switch appear on DG1 pin 37.
DG
Board
The
DG Board is responsible for processing all incoming video signals from the A
board. The video input input signals are processed and converted into the LCD
format required to drive the LCD Panel. This is accomplished by the main global
core IC GC3FM (IC4011) and Video Signaling Processing IC4002.
The
Microcontroller, IC1106 (DG board), controls the incoming video signals on the Combo
Unit (TC22LR30) in the same way as it does on the TC-26/32LX20.The difference, however, is the addition of a serial data line between IC1106 and
the Microcontroller IC7501, located on the DVD RD board.
The
main Microcontroller IC 1106 is responsible for:
* Decodes
the remote control input code.
* Provides
Channel selection
* Global
Core control
* Sound
volume control
* OSD
Display.
The OSD data that pertains Microcontroller (IC6001), which resides on the M8 board. The TV OSD is mixed with
the DVD OSD on this board and is fed to the Video Switch is located on the A
Board.
Video
Signal Processing
All
NTSC video signals are converted to digital data by the analog to digital (A/D)
converter circuit located inside the Global Core IC, IC4011. The comb filter in
IC40 converts the composite video signal of the main picture to Y and C separated
video data. The S-Video signal, which is already Y/C separated, by Chroma
information is then applied to the Chroma Demodulator circuit that separates the
color signal into PB and PR data. The
Component inputs, which are already Y/C, separated; are converted to digital bypass
the comb filter section of this IC4011. The 480p and 1080i ATSC Video signals simply
pass through the IC (which IC) and are output to the main global core IC, IC4011.
Interlace
to progressive (I/P) conversion for the 480i video format is accomplished via
the Video Signaling Processing IC, IC4010, and SDRAM IC4018 which serves as a
temporary buffer during the interlaced to progressive conversion process. The
Video signal Processing IC is responsible for Pixel conversion, White Balance,
Aspect Ratio version, Image resizing and LCD Panel control.
Low
Voltage Differential Signaling
The
method used to transfer the video information from the Main circuit board to the
LCD drive circuit is called Low Voltage Differential Signaling (LVDS). LVDS
devices typically consume less power than other signaling systems such as TTL. LVDS
device use a constant current driver. Therefore, power consumption is
independent of frequency. The LVDS interface voltage is much less than TTL, approximately 2V.
The voltage swing is typically 350mV with an offset of 1.25V. Integrated
circuits based on VDS technology distribute signals with low-jitter, while
creating little noise. In this
application, three 8-bit streams of data are converted from parallel to serial
and interleaved. The interleave process makes the data less susceptible to
noise. The peak to peak voltage level is
reduced as well. The lower voltage level reduces the power consumption and the
generated noise from data transmission.
Another benefit of the LVDS standard is minimal concern for cable
length. The data rates for LVDS are 110 Mbps for a 1-meter distance, dropping
to 90 Mbps over a 10-meter distance.
HDMI Signal Path
The HDMI (High Definition Multimedia Interface) resides on the DV board and serves as an input port designed to receive digital video and audio from a set-top box, a DVD player or other digital devices. IC5003 converts the digital video to parallel analog RGB video. The outgoing audio is converted to analog via IC5006 and
IC5007. EEPROM IC5001 serves as the content protection circuit and monitors the HDMI signal for copyright protection. IC5005 selects between HDMI and DVI audio.
[If the external device has DVI output only, use a DVI to HDMI adaptor cable in order to connect to the HDMI jack to the DV HDMI connector. Also, connect the Audio Out signal from the external device (set top box or DVD player) to the Audio In jacks. An HDMI to DVI conversion cable (TY-SCH03DH) is available at the Panasonic parts department.]
Self-Check Function for TV Section
The self-check feature is designed to check if a particular component is functioning and it does not actually diagnose the problem .For example “Tuner Check OK” doesn’t’ necessarily mean that it is OK. It pings or selectively addresses that particular device via the I2 Bus to determine if it exists. The same holds true for the Global Core IC’s, the MTS, the Sound circuit, and the Audio/Video switches. However, it should be noted that the displayed results could be misleading by indicating that it is OK.
The troubleshooting section of this document is intended to provide the necessary guidance and assistance in the fault isolation of a particular problem and will serve as a diagnostic tool for troubleshooting.
Self-Check
Access
To access the self check mode
Press the VOLUME-Down Button on the unit and SLEEP button on the remote at the same time. To exit press any key.
Servicing
the TV Portion
Service
Adjustment Mode for TV
Purpose of Adjustment mode
Adjustment mode provides the technician with the ability to perform standard
video an audio adjustments.
To
enter the Adjustment mode
While
the unit is powered on, hold down the “Volume Down” button on the unit while
pressing the “Display” button on the remote three times (within 2
seconds). The service adjustment mode
menu will appear.
Service
mode is broken down into two categories, Main Items, which are all displayed on
the menu screen and Sub Items.
How
to navigate the Adjustment mode
Use the number buttons “1” and “2” on the remote control to change the Main
Item. The number “1” button will cycle from the MAIN option down to the DVD
option. The number “2” button will cycle in reverse direction.
Use
the number buttons “3” and “4” on the remote control to cycle through the Sub
Items until the proper adjustment is reached.
Adjustment
of the Sub Item is made using the “Volume” buttons on the remote control.
Data changes are saved automatically when you switch Sub or Main Items, or if
you exit the service mode.
Note: When the DVD adjustments are accessed, the unit switches to the DVD mode.
The software version of the DVD Player can be displayed here.
How
to exit Adjustment mode
Switch off the “Power” button on the main unit or press the “Power” button on
the remote control.
Warning: If you are making adjustments in the service mode, keep a record of
the data value before making the adjustment.
Servicing
the DVD
Service
Tools
This is a list of the service equipment that portion of the LCD TV Combo.
DVD
Test Disc DVDT-S01 and DVDT-S15 (Supplied from SPC.)
* Extension cable REKZ0214 (Supplied from SPC)
Shakanabi
Software: Not supplied as service parts. (This software is used for the repair
of Circuit Board M8.)
Data
change CD-R: Not supplied as service parts. (This CD-R is used for the repair
of Circuit Board M8.)
M8
Circuit Board repair
Change
what is referred to as the model setting data for the software that resides in
IC6702. This converts TC-22LR30 [the DVD portion] to that of a DMR-E65 for ease
in troubleshooting. This is accomplished
through the use of the Shakanabi Software.
Repair Circuit Board M8 as you would rep
DMR-E65 DVD Recorder. Upon completion setting data back to that of the TC22LR30. Use the Data change CD-R to accomplish the task.
Troubleshooting
Shutdown
Problems
If
a problem occurs in either the unit or power supply a protection circuit is activated
and the unit shuts down. The Power indicator on the front of the unit will
flash red several times indicating an error code. Error codes vary for
different models.
LED
Flashes Once every 5 seconds.
Check
the Backlight supply voltage from the P board.
> TC22LR30 -15 volts P2 pin 9-15 Ground pins 1-7.
> TC26/32LX20- 120 volts P4 pins 1-2. Ground Pins 4-7
LED
Flashes Five Times
Check
the Main 9Volts Regulator Q801 on the AP Board
LED
Flashes Eight Times
Check
the Sub 5 Volts regulator, IC808.
Unit
shuts down and the Power on LED is off.
Check
the SOS Shutdown and over-voltage protection circuits.
SOS
Shutdown Problem
If
the unit keeps shutting down check the SOS Shutdown line at pin 9 of connector
DG2.
It
should be at a high level. Anodes of D877, D878, D880, D844 all should be high.
Backlighting
Backlighting
Brightner Panasonic’s line of LCD TVs is accomplished through the use of Cold
Cathode Fluorescent tubes (CCFL), which is currently the light source of choice, by a number of leading manufacturers.
Inverter
Power Supply
Pulse
width modulation is a very straight forward the CCF tube(s). The inverter is
turned on and off (using the input or an enable/disable line) from the
Microprocessor Unit (MPU) to control cycle is lengthened to increase the
brightness and reduced to decrease the brightness. One of the major advantages
of pulse width modulation is the tube is always fully “on” or fully “off” and
full starting voltage is always applied to the tube(s) (assuming nominal input
voltage).
High
Voltage power supply
A
CCF tube needs high voltage. The starting voltage is generally over 1,000 volts
and bettween 200 and 500 volts rms.
Most CCFT DC to AC inverters are tuned switchers designed to produce a specific
voltage, frequency and output current when a designated tube is connected to
the output. The classic current-fed two-transistor inverter has a tuned resonating
output, tuned resonating input and inductive dc input which provides for good
power transfer and high operating efficiency.
The
type of circuit depicted inherently produces a pure sine-wave output, but the
voltage and current waveforms are both distorted when they are applied to a CCFL tube, which is a highly nonlinear device. The transition from the starting
voltage to the operating vented by a small internal series output capacitor
which serves as the ballast providing impedance and allowing proper tube
current after the tube has been ignited.