Panasonic Z8 / Chassis Service Manual / Other ▷ View online
3DQDVRQLF
:
Pins 58 / 59 - XTALIN / XTALOUT
The internal oscillator of the UOC IC is synchronised
with an external 12MHz quartz crystal X601 which is
connected to pins 58 and 59.
The clock frequencies for the I
with an external 12MHz quartz crystal X601 which is
connected to pins 58 and 59.
The clock frequencies for the I
2
C bus system are also
obtained from this frequency by internal dividing.
The same 12MHz clock signal is also divided down
and used to synchronise the video processing stage.
The same 12MHz clock signal is also divided down
and used to synchronise the video processing stage.
:
Pin 60 - Reset
During power On/Off operation, or during a fall in
voltage to the UOC IC, incorrect operation may occur.
To prevent this incorrect operation, the UOC IC has
a reset signal input via pin 60.
The reset signal is provided by reset IC IC1102 pin 1,
which keeps the UOC IC in a stable condition until the
voltage level has risen and become stabilised. This
reset IC IC1102 which is fed a 3.3V standby supply,
is input via pin 2.
voltage to the UOC IC, incorrect operation may occur.
To prevent this incorrect operation, the UOC IC has
a reset signal input via pin 60.
The reset signal is provided by reset IC IC1102 pin 1,
which keeps the UOC IC in a stable condition until the
voltage level has risen and become stabilised. This
reset IC IC1102 which is fed a 3.3V standby supply,
is input via pin 2.
:
Pin 64 - Remote IN
The commands required for control of the TV receiver
are applied from the remote control.
The command from the remote control transmitter is
applied via IC1104, RPM-637BRS remote control
receiver to pin 64 of the UOC IC. This command data
is received in serial format.
are applied from the remote control.
The command from the remote control transmitter is
applied via IC1104, RPM-637BRS remote control
receiver to pin 64 of the UOC IC. This command data
is received in serial format.
4.1.2. Output Control
:
Pin 1 - Standby
This output port of the UOC IC is used to control the
switching of the TV in and out of standby. The signal
path from this output at pin 1 follows two paths.
switching of the TV in and out of standby. The signal
path from this output at pin 1 follows two paths.
The first path is fed via the controlling transistor
Q1204. A High level is applied from pin 1 to the base
of transistor Q1204, causing Q1204 to switch On.
This in turn causes Q1201 to switch Off, preventing
current flow via the winding of the standby relay
RL801. This results in the mains AC supply being
removed from the power supply circuit.
Likewise when a low level is fed to the base of Q1204,
the transistor is biased Off, thus allowing transistor
Q1201 to conduct by a High level which is applied via
R1205. When Q1201 conducts, current via the
standby relay causes the relay contact to close and
feed the mains AC voltage to the power circuit.
Q1204. A High level is applied from pin 1 to the base
of transistor Q1204, causing Q1204 to switch On.
This in turn causes Q1201 to switch Off, preventing
current flow via the winding of the standby relay
RL801. This results in the mains AC supply being
removed from the power supply circuit.
Likewise when a low level is fed to the base of Q1204,
the transistor is biased Off, thus allowing transistor
Q1201 to conduct by a High level which is applied via
R1205. When Q1201 conducts, current via the
standby relay causes the relay contact to close and
feed the mains AC voltage to the power circuit.
The second path is fed via resistor R1141 to the
collector of transistor Q1109. During standby, the
High level applied from pin 1 to collector Q1109
collector of transistor Q1109. During standby, the
High level applied from pin 1 to collector Q1109
causes Q1107 to conduct, switching the LED D1104
On.
When an operating command is used either from the
local keys or remote control, the keyscan output pin
6 of IC601 is pulled Low, causing transistor Q1102 to
switch Off. This results in the base of transistor Q1109
to go High due to pull up resistor R1146, to switch
Q1109 On. Q1110 also conducts pulling the base of
Q1107 Low, thus switching it Off. This results in the
standby LED D1104 switching Off.
On.
When an operating command is used either from the
local keys or remote control, the keyscan output pin
6 of IC601 is pulled Low, causing transistor Q1102 to
switch Off. This results in the base of transistor Q1109
to go High due to pull up resistor R1146, to switch
Q1109 On. Q1110 also conducts pulling the base of
Q1107 Low, thus switching it Off. This results in the
standby LED D1104 switching Off.
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Pin 4 - L/L’
Pin 4 of the UOC IC IC601 is used to select between
the two types of SECAM standards L/L’. This control
signal is used on SECAM L models only.
the two types of SECAM standards L/L’. This control
signal is used on SECAM L models only.
:
Pin 5 - CATS Eye
Pin 5 of the UOC IC is used to control a feature known
as CATS (Contrast Automatic Tracking System).
This is used to adjust the contrast level depending on
the external light surrounding the TV. The level of the
adjustment made is dependant upon the mode
selected via the OSD (Medium / Maximum).
The light sensed by the LDR (Light Dependant
Resistor) R1283 is used to control the conduction of
transistor Q1101 which in turn, controls the voltage
level at pin 49 of IC601 and thus, the contrast level.
as CATS (Contrast Automatic Tracking System).
This is used to adjust the contrast level depending on
the external light surrounding the TV. The level of the
adjustment made is dependant upon the mode
selected via the OSD (Medium / Maximum).
The light sensed by the LDR (Light Dependant
Resistor) R1283 is used to control the conduction of
transistor Q1101 which in turn, controls the voltage
level at pin 49 of IC601 and thus, the contrast level.
:
Pin 7 - Neg / Pos
This output control is used to select between
PAL/NTSC (Negative modulation) and SECAM
(Positive modulation) standards selection.
PAL/NTSC (Negative modulation) and SECAM
(Positive modulation) standards selection.
Pin 7 is also used as an input on UK models only, to
achieve the highest possible signal from the tuner via
Q001.
achieve the highest possible signal from the tuner via
Q001.
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Pin 11 - Mute
The mute control which is output from the UOC IC pin
11 is fed to the audio output IC IC251 pin 3 via Q255.
Pin 11 of IC601 which is pulled Low for normal
operation, is biased by resistor R1141 to the 5V
standby supply.
11 is fed to the audio output IC IC251 pin 3 via Q255.
Pin 11 of IC601 which is pulled Low for normal
operation, is biased by resistor R1141 to the 5V
standby supply.
During
channel
change,
tuning
and
muting
operations, the Low level output from pin 11 is
disabled causing the base of Q255 to go High,
switching it On. This results in pin 3 of IC251 being
pulled Low, resulting in the audio output being muted.
Muting is also provided for audio POP during On/Off
operation via transistor Q253, the operation of which
is discussed in section 11.2.1.
disabled causing the base of Q255 to go High,
switching it On. This results in pin 3 of IC251 being
pulled Low, resulting in the audio output being muted.
Muting is also provided for audio POP during On/Off
operation via transistor Q253, the operation of which
is discussed in section 11.2.1.
3DQDVRQLF
4.1.3. Q-Link
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Pin 62 - Q-Link_In / Pin 63 - Q-Link_Out
Q-Link input and output is a model dependant
function used to control the transfer of information
and user functions to and from the TV / VCR via AV
21 pin socket JK3102.
The AV link control line fed from pin 10 of the 21 pin
AV socket is fed to the Q-Link circuit made up of
Q1103, Q1106, Q1105 and Q1104.
Where data is fed from the TV to the VCR, the Q-Link
output terminal pin 63 of the UOC IC IC601 is used.
This results in the data being fed from pin 63 of the
UOC IC IC601 via Q1106.
Where data is input from the VCR to the TV, then the
Q-Link In terminal pin 62 of the UOC IC IC601 is used.
This results in data being fed via Q1103, Q1105 and
Q1104 to the UOC IC IC601 pin 62.
function used to control the transfer of information
and user functions to and from the TV / VCR via AV
21 pin socket JK3102.
The AV link control line fed from pin 10 of the 21 pin
AV socket is fed to the Q-Link circuit made up of
Q1103, Q1106, Q1105 and Q1104.
Where data is fed from the TV to the VCR, the Q-Link
output terminal pin 63 of the UOC IC IC601 is used.
This results in the data being fed from pin 63 of the
UOC IC IC601 via Q1106.
Where data is input from the VCR to the TV, then the
Q-Link In terminal pin 62 of the UOC IC IC601 is used.
This results in data being fed via Q1103, Q1105 and
Q1104 to the UOC IC IC601 pin 62.
The type of data and function control information fed
via the Q-Link is as follows:
via the Q-Link is as follows:
:
TV Auto Power ON: TV automatically turns ON
when the VCR starts play-back.
when the VCR starts play-back.
:
VCR Auto Standby: VCR will automatically
switch to standby when the TV is turned OFF,
unless the VCR is in recording mode.
switch to standby when the TV is turned OFF,
unless the VCR is in recording mode.
:
TV On screen Display of VCR status.
:
Download of Country selection.
These above features will only work with a Panasonic
TV / video combination which are both Q-Link
(Project 50+) compliant.
The features below will work with different brands of
TV and video combinations, again as long as both TV
and video are Project 50 compliant.
TV / video combination which are both Q-Link
(Project 50+) compliant.
The features below will work with different brands of
TV and video combinations, again as long as both TV
and video are Project 50 compliant.
:
Tuner preset data down load (TV->VCR)
:
What You See Is What You Record (Direct TV)
In addition to these features the TV/Video also
include in their protocol Automatic signal matching
(signal quality). Here the TV/video at first time of
connecting, exchange information regarding features
and operational capabilities, such as signal standards
and the ability to process and display 16:9 format, for
example.
include in their protocol Automatic signal matching
(signal quality). Here the TV/video at first time of
connecting, exchange information regarding features
and operational capabilities, such as signal standards
and the ability to process and display 16:9 format, for
example.
4.1.4. I
2
C Bus
:
Pins 2 / 3 - SCL / SDA
The I
2
C bus is a two-wire Bus system consisting of a
data line and a clock line. This BUS system allows
serial and bidirectional communications exchange
between several devices which include an I
serial and bidirectional communications exchange
between several devices which include an I
2
C bus
interface. The number of connections are therefore
reduced, which results in a simplified circuit design
and
reduced, which results in a simplified circuit design
and
increased
reliability
(less
soldered
joints/connections and contacts).
Within the the UOC IC, the microcontroller stage and
the signal processing stage utilise this Bus.
Within the the UOC IC, the microcontroller stage and
the signal processing stage utilise this Bus.
3DQDVRQLF
4.2. Colour TV Signal Processing
The TDA9350/60/80 series of the Ultimate One Chip
(UOC) IC IC601 incorporates all the functions
necessary for processing of audio and video signals.
The following sections will include the video input and
output control, IF signal path, colour decoder and
RGB processing stages. Horizontal and Vertical
synchronisation are also included. The elements
required by the UOC IC to perform these functions
are:
(UOC) IC IC601 incorporates all the functions
necessary for processing of audio and video signals.
The following sections will include the video input and
output control, IF signal path, colour decoder and
RGB processing stages. Horizontal and Vertical
synchronisation are also included. The elements
required by the UOC IC to perform these functions
are:
:
Multistandard vision IF circuit with constant PLL
demodulator
demodulator
:
Mono intercarrier sound FM demodulator or
QSS IF amplifier
QSS IF amplifier
:
Internal IF AGC timing
:
CVBS (internal/external) or Y/C signal source
selection
selection
:
Integrated chrominance trap circuit
:
Integrated luminance delay line with adjustable
delay time
delay time
:
Asymmetrical peaking in the luminance channel
:
Black stretching for non-standard luminance
signals
signals
:
Integrated
chroma
bandpass
filter
with
switchable centre frequency
:
PAL/NTSC or multistandard colour decoder with
automatic search system
automatic search system
:
internal baseband delay line
:
RGB control circuit with ’Continuous Cathode
Calibration’ and colour temperature option
Calibration’ and colour temperature option
:
Linear RGB or YUV input with fast blanking for
external RGB/YUV sources
external RGB/YUV sources
:
Horizontal synchronisation with two control loops
and alignment-free horizontal oscillator
and alignment-free horizontal oscillator
:
Vertical count-down circuit
:
Vertical driver optimized for DC coupled vertical
output stages
output stages
:
Horizontal and vertical geometry processing
:
Horizontal and vertical zoom function for 16:9
applications
applications
:
Horizontal parallelogram and bow correction for
large screen picture tubes
large screen picture tubes
3DQDVRQLF
4.3. IF Signal Processing
General
The IF signal processing for the Z8 chassis is carried
out by IC601. There are two main types of IF circuit
configurations used depending on the UOC IC device
used, these differences will be covered in the
following sections.
out by IC601. There are two main types of IF circuit
configurations used depending on the UOC IC device
used, these differences will be covered in the
following sections.
4.3.1. Video (VIF) Processing Signal Path
The RF signal received by the tuner TNR001 is output
via terminals IF1 and IF2. This IF signal is necessary
for processing of video (VIF) and sound (SIF) signals.
Here the signal path varies, depending on the version
of UOC IC used.
via terminals IF1 and IF2. This IF signal is necessary
for processing of video (VIF) and sound (SIF) signals.
Here the signal path varies, depending on the version
of UOC IC used.
For stereo models, the IF signal is passed through the
SAW filter X103, where separation of the VIF and SIF
signals occur. Here, the VIF signals are fed to IC601
pins 23 and 24 where video processing takes place.
The
SAW filter X103, where separation of the VIF and SIF
signals occur. Here, the VIF signals are fed to IC601
pins 23 and 24 where video processing takes place.
The
internal
circuit
provides
amplification,
demodulation and filtering. The signal level is
monitored by the internal AGC detector and the
information is fed back to the tuner via pin 27 of IC601.
monitored by the internal AGC detector and the
information is fed back to the tuner via pin 27 of IC601.
For mono models, the IF signal path sees the IF signal
being fed to the intercarrier SAW filter X102. From
here the signal feeds the UOC IC IC601 via pins 23
and 24 where video processing takes place internally.
being fed to the intercarrier SAW filter X102. From
here the signal feeds the UOC IC IC601 via pins 23
and 24 where video processing takes place internally.
4.3.2. Sound (SIF) Processing Signal Path
As already mentioned, the IF signal fed from the tuner
is necessary for the processing of sound (SIF)
signals.
is necessary for the processing of sound (SIF)
signals.
Once again,
the signal path varies,
depending on the version of UOC IC used.
For stereo models, the SIF signal fed from the SAW
filter X103 is applied to IC601 pins 28 and 29, where
signal processing is provided internally within the IC.
Here the signal is split into two paths.
filter X103 is applied to IC601 pins 28 and 29, where
signal processing is provided internally within the IC.
Here the signal is split into two paths.
The first path feeds the signal through an internal
Quasi Stereo Sound (QSS) mixer and bandpass filter,
to produce a QSS IF output at pin 35 via the audio
switching circuit.
Quasi Stereo Sound (QSS) mixer and bandpass filter,
to produce a QSS IF output at pin 35 via the audio
switching circuit.
For mono models, the SIF signal path is fed to IC601
pins 23 and 24 via the intercarrier SAW filter X102. As
already mentioned, separation of the VIF and SIF
signals occur internally within the UOC IC.
pins 23 and 24 via the intercarrier SAW filter X102. As
already mentioned, separation of the VIF and SIF
signals occur internally within the UOC IC.
4.4. SECAM IF Signal Processing
General
Those models which are capable of processing
SECAM L signals have an additional IF signal path
SECAM L signals have an additional IF signal path
from the tuner to the relevant video and audio signals
that are required.
that are required.
The IF signal is fed from the tuner TNR001 via two
trap circuits, made up of X101, L105 and L106. For
SECAM processing, the IF signal splits into two
paths. These are discussed in the following sections.
trap circuits, made up of X101, L105 and L106. For
SECAM processing, the IF signal splits into two
paths. These are discussed in the following sections.
4.4.1. Video (VIF) Processing Signal Path
For VIF processing of mono TVs, the IF signal is fed
from the tuner and via the intercarrier SAW filter
X102. This results in the VIF signal being input via
pins 23 and 24 of the UOC IC IC601.
from the tuner and via the intercarrier SAW filter
X102. This results in the VIF signal being input via
pins 23 and 24 of the UOC IC IC601.
For stereo models, the IF signal is fed via the SAW
filter X102 where the VIF signal is extracted before
being fed to IC601 pins 23 and 24.
filter X102 where the VIF signal is extracted before
being fed to IC601 pins 23 and 24.
4.4.2. Sound (SIF) Processing Signal Path
For mono models, the IF signal is fed from the tuner
and via the amplifier transistor Q204 and L/L’
switching circuit, made up of transistors Q202, Q203
and filter X201. The L/L’ operation is controlled by the
UOC IC IC601 pin 4 where the signal path is
determined by the switching of the control transistor
Q202.
During L mode operation, pin 4 of IC601 is pulled low
causing transistor Q202 to be switched Off. With the
voltage at the collector of Q202 being High, the IF
signal will flow via transistor Q204, diode D202 and
pin 2 of filter X201. At the same time, transistor Q203
switches on causing the L’ input pin 1 of X201 to be
pulled Low, muting its operation.
During L’ mode operation, pin 4 of IC601 is held high
by resistor R209 causing transistor Q202 to switch
on. The voltage at the collector of Q202 is Low,
causing the IF signal to flow via transistor Q204,
diode D201 and pin 1 of filter X201. At the same time,
the L input pin 2 of X201 is pulled Low via transistor
Q203, muting its operation.
The SIF signal from X201 is fed via the IF inputs pins
1 and 16 of the AM demodulator/audio switch IC201.
The audio output at pin 8 is fed to the buffer transistor
Q208. Transistor Q209 is used to provide muting of
the audio signal when no SECAM signal is present at
the tuner input. Pin 7 of IC601 provides the trigger
voltage to Q209, the level being determined by the
presence of either positive (SECAM) or negative
(PAL/NTSC) modulation. From here the signal
follows two paths.
The first path feeds the audio signal to the UOC IC
IC601 pin 28 for further processing.
The second path sees the audio signal being output
via transistors Q3101 and Q3102 to the AV 21 pin
scart pins 1 and 3.
and via the amplifier transistor Q204 and L/L’
switching circuit, made up of transistors Q202, Q203
and filter X201. The L/L’ operation is controlled by the
UOC IC IC601 pin 4 where the signal path is
determined by the switching of the control transistor
Q202.
During L mode operation, pin 4 of IC601 is pulled low
causing transistor Q202 to be switched Off. With the
voltage at the collector of Q202 being High, the IF
signal will flow via transistor Q204, diode D202 and
pin 2 of filter X201. At the same time, transistor Q203
switches on causing the L’ input pin 1 of X201 to be
pulled Low, muting its operation.
During L’ mode operation, pin 4 of IC601 is held high
by resistor R209 causing transistor Q202 to switch
on. The voltage at the collector of Q202 is Low,
causing the IF signal to flow via transistor Q204,
diode D201 and pin 1 of filter X201. At the same time,
the L input pin 2 of X201 is pulled Low via transistor
Q203, muting its operation.
The SIF signal from X201 is fed via the IF inputs pins
1 and 16 of the AM demodulator/audio switch IC201.
The audio output at pin 8 is fed to the buffer transistor
Q208. Transistor Q209 is used to provide muting of
the audio signal when no SECAM signal is present at
the tuner input. Pin 7 of IC601 provides the trigger
voltage to Q209, the level being determined by the
presence of either positive (SECAM) or negative
(PAL/NTSC) modulation. From here the signal
follows two paths.
The first path feeds the audio signal to the UOC IC
IC601 pin 28 for further processing.
The second path sees the audio signal being output
via transistors Q3101 and Q3102 to the AV 21 pin
scart pins 1 and 3.
For stereo models, the IF signal is fed from the tuner
via the amplifier transistor Q204 and L/L’ switching
circuit as mentioned above. The SIF signal from X201
is fed via pins 28 and 29 of the UOC IC IC601.
via the amplifier transistor Q204 and L/L’ switching
circuit as mentioned above. The SIF signal from X201
is fed via pins 28 and 29 of the UOC IC IC601.
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