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3.8. Protection Circuitry
3.8.1. Over-voltage Protection (OVP)
Over-voltage Protection is used to protect IC801 if V
IN
pin 4 terminal rises to approximately 22V. Although it
basically functions as protection for pin 4 against
overvoltage, it is also used to protect against
overvoltage of the secondary output (in the event of
failure of the regulation, for example). This is because
pin 4 is supplied by winding B1-B2 of transformer
T802, this voltage being proportional to the output
voltage of the secondary side.
basically functions as protection for pin 4 against
overvoltage, it is also used to protect against
overvoltage of the secondary output (in the event of
failure of the regulation, for example). This is because
pin 4 is supplied by winding B1-B2 of transformer
T802, this voltage being proportional to the output
voltage of the secondary side.
3.8.2. Over-current Protection (OCP)
Overcurrent Protection is performed pulse-by-pulse
by directly detecting the drain current of the internal
power MOSFET. Since the detection voltage is
monitored by an internal comparator of IC801,
constant temperature stabilisation is also achieved.
by directly detecting the drain current of the internal
power MOSFET. Since the detection voltage is
monitored by an internal comparator of IC801,
constant temperature stabilisation is also achieved.
The
Drain-Source
current
through
the power
switching MOSFET is passed via the resistor R809,
which develops a voltage across it. The input voltage
to IC801 pin 1 (OCP/FB) is passed to an internal
comparator. When this input voltage exceeds a
pre-determined value, the drive output is pulled LOW,
resulting in the power MOSFET switching OFF.
which develops a voltage across it. The input voltage
to IC801 pin 1 (OCP/FB) is passed to an internal
comparator. When this input voltage exceeds a
pre-determined value, the drive output is pulled LOW,
resulting in the power MOSFET switching OFF.
3.8.3. Latch
The latch circuit is used to pull the output of the
oscillator LOW (switching MOSFET OFF) when the
over-voltage protection or thermal shutdown circuits
are activated.
oscillator LOW (switching MOSFET OFF) when the
over-voltage protection or thermal shutdown circuits
are activated.
16V
10V
t
In this condition the V
IN
terminal pin 4 decreases until
the shutdown voltage of 10V is reached. At this point
pin 4 begins to rise again but when it reaches the start
up level of 16V, the latch circuit continues to stop the
drive.
When the latch is on, V
pin 4 begins to rise again but when it reaches the start
up level of 16V, the latch circuit continues to stop the
drive.
When the latch is on, V
IN
voltage at pin 4 increases
and decreases within the range 10V to 16V, as shown
in the above diagram, and is prevented from rising
normally.
in the above diagram, and is prevented from rising
normally.
Cancellation of the latch circuit operation is achieved
by restarting the AC input to the circuit after switching
off the TV.
by restarting the AC input to the circuit after switching
off the TV.
3.8.4. Thermal Shutdown
This circuit triggers the latch when the body
temperature
temperature
of
the
IC
exceeds
140
E
C.
The
temperature is sensed by the control IC, but also
works against overheating of the MOSFET, as both
are mounted on the same lead frame.
works against overheating of the MOSFET, as both
are mounted on the same lead frame.
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3.9. Secondary Supplies
On the secondary side, the transformer T802
supplies the following voltages:
supplies the following voltages:
:
+12V to supply the horizontal driver stage.
:
+20V to supply the East/West correction IC
IC701.
IC701.
:
+27V to supply the audio output IC IC251.
3.9.1. +12V Supply
The signal from pin 16 of T802 is rectified by diode
D851 and smoothed by capacitor C856. The 12V
supply voltage is then applied to the horizontal driver
transformer T553 via diode D501 and resistor R503.
During start-up, the 12V supply feeds the horizontal
stage as mentioned. However, when the whole power
supply is up and running normally, the supply voltage
from the secondary of T802 is no longer required. The
horizontal stage now takes its 12V supply from the
FBT T552. This is required to reduce the load on the
secondary and provide drive current to the horizontal
driver transformer T553.
D851 and smoothed by capacitor C856. The 12V
supply voltage is then applied to the horizontal driver
transformer T553 via diode D501 and resistor R503.
During start-up, the 12V supply feeds the horizontal
stage as mentioned. However, when the whole power
supply is up and running normally, the supply voltage
from the secondary of T802 is no longer required. The
horizontal stage now takes its 12V supply from the
FBT T552. This is required to reduce the load on the
secondary and provide drive current to the horizontal
driver transformer T553.
3.9.2. +20V Supply
The signal from pin 14 of T802 is rectified by diode
D853 and applied to the series regulator IC702 to
supply +20V to the East/West circuit (model
dependant).
D853 and applied to the series regulator IC702 to
supply +20V to the East/West circuit (model
dependant).
3.9.3. +27V Supply
The signal from pin 14 of T802 is rectified by diode
D853 and applied to the emitter terminals of
transistors Q851 and via resistor R855 to Q852. This
voltage to Q852 is fed via the emitter/collector
junction. At the same time, the signal from pin 13 of
T802 is rectified by diode D852 to provide a voltage
of +27V, which is fed to the audio output IC IC251.
D853 and applied to the emitter terminals of
transistors Q851 and via resistor R855 to Q852. This
voltage to Q852 is fed via the emitter/collector
junction. At the same time, the signal from pin 13 of
T802 is rectified by diode D852 to provide a voltage
of +27V, which is fed to the audio output IC IC251.
This supply voltage of +27V however is too large for
the above mentioned ICs when under load and so the
supply voltage has to be reduced. As the load on the
above ICs increases, the voltage drop across R856
increases causing the base of Q851 to become more
negative with respect to its emitter. With Q851
conducting the base bias of Q852 becomes more
positive with respect to its emitter, thus causing the
supply voltage to the ICs to be reduced.
However by reducing the supply voltage to IC251, the
the above mentioned ICs when under load and so the
supply voltage has to be reduced. As the load on the
above ICs increases, the voltage drop across R856
increases causing the base of Q851 to become more
negative with respect to its emitter. With Q851
conducting the base bias of Q852 becomes more
positive with respect to its emitter, thus causing the
supply voltage to the ICs to be reduced.
However by reducing the supply voltage to IC251, the
output power is also reduced. This is compensated
for by the increased current flow via R853 / R854. This
in turn ensures that the output power of the ICs is not
affected.
for by the increased current flow via R853 / R854. This
in turn ensures that the output power of the ICs is not
affected.
3.10. Voltage Supplies
3.10.1. +12V Supply
The +12V supply is output from transformer T552 pin
4 and is rectified by diode D553. This rectified voltage
is smoothed by capacitor C566 before being fed to the
vertical output IC IC451 pin 6. The +12V supply also
feeds the horizontal driver transformer T553 via diode
D510 and resistor R503.
4 and is rectified by diode D553. This rectified voltage
is smoothed by capacitor C566 before being fed to the
vertical output IC IC451 pin 6. The +12V supply also
feeds the horizontal driver transformer T553 via diode
D510 and resistor R503.
3.10.2. -12V Supply
The -12V supply is output from transformer T552 pin
5 and is rectified by diode D559. This negative voltage
is smoothed by capacitor C564 before being fed to the
ground terminal pin 1 of the vertical output IC IC451.
5 and is rectified by diode D559. This negative voltage
is smoothed by capacitor C564 before being fed to the
ground terminal pin 1 of the vertical output IC IC451.
3.10.3. +10V Supply
A supply of approximately 10V is output from
transformer T552 pin 6, and fed to diode D554. This
rectified voltage signal is then smoothed by capacitor
C554 before being fed to the series regulator IC852
and the standby voltage regulator IC1202.
transformer T552 pin 6, and fed to diode D554. This
rectified voltage signal is then smoothed by capacitor
C554 before being fed to the series regulator IC852
and the standby voltage regulator IC1202.
3.10.4. +8V Supply
The 8V supply is derived from the 10V supply line
which is fed to the series regulator IC852 pin 1. The
output of IC852 pin 3, smoothed by capacitor C857,
is used to supply 8V to the TV control processor IC
IC601, RGB output stage (Y-Board) via connectors
E8 and Y2 pin 6, sound processor IC2001 and
SECAM IF audio switching IC IC201 (French models
only). IC852 also supplies the 5V series regulator IC
IC851.
which is fed to the series regulator IC852 pin 1. The
output of IC852 pin 3, smoothed by capacitor C857,
is used to supply 8V to the TV control processor IC
IC601, RGB output stage (Y-Board) via connectors
E8 and Y2 pin 6, sound processor IC2001 and
SECAM IF audio switching IC IC201 (French models
only). IC852 also supplies the 5V series regulator IC
IC851.
3.10.5. +5V Supply
The 5V supply is derived from the 8V supply line
which is fed to IC851 pin 1. The output at pin 3,
smoothed by capacitor C851, is used to supply 5V to
the tuner, reset IC IC1105 and the sound processor
IC2001 (model dependant).
which is fed to IC851 pin 1. The output at pin 3,
smoothed by capacitor C851, is used to supply 5V to
the tuner, reset IC IC1105 and the sound processor
IC2001 (model dependant).
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4.
TV Signal, Control and Teletext Processing
The TDA9350/60/80 series IC601 used on Z8
chassis, is a one chip solution in TV processing. The
Philips Ultimate One Chip (UOC) IC combines the
functions of a TV signal processor and teletext
decoder as well as an embedded microcontroller
chassis, is a one chip solution in TV processing. The
Philips Ultimate One Chip (UOC) IC combines the
functions of a TV signal processor and teletext
decoder as well as an embedded microcontroller
used to perform control processing. The TV signal
and teletext processing stages will be looked at later.
First, the control processing stage of the UOC IC will
be examined.
and teletext processing stages will be looked at later.
First, the control processing stage of the UOC IC will
be examined.
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4.1. Control Processing Stage
The elements that the UOC IC required to perform the
control functions are:
control functions are:
:
80C51 microcontroller
:
12MHz internal clock
:
32 - 128K x 8 bit late programmed ROM
:
3 - 12K x 8 bit Auxiliary RAM
:
Interrupt controller for individual enable/disable
:
Two 16 bit Timer/Counter registers
:
WatchDog timer
:
Serial Interface
:
IDLE and Power Down (PD) mode
:
14 bits Pulse Width Modulation for Voltage
Synthesis Tuning
Synthesis Tuning
:
8 bit A/D Converter
:
Programmable as general I/O, ADC input or
PWM (6-bit) output
PWM (6-bit) output
4.1.1. Input Control
:
Pin 6 - Keyscan
The local commands are fed to the UOC IC IC601 as
serial data. This data is input via pin 6. This pin is held
at 3.3V due to the pull-up resistor R1140, which is
connected to the 3.3V standby supply. This means
that the High level is also maintained during standby
condition. Operating commands fed from the local
keys results in varying voltages being applied to pin
6, which in turn initiates the various controls.
When operating commands are fed via the remote
control to pin 64 of IC601, pin 6 of IC601 also outputs
a pulse, which feeds transistors Q1102 and Q1107 to
provide a flashing standby LED D1104.
Operating commands issued from the local and
remote control are treated with equal status.
serial data. This data is input via pin 6. This pin is held
at 3.3V due to the pull-up resistor R1140, which is
connected to the 3.3V standby supply. This means
that the High level is also maintained during standby
condition. Operating commands fed from the local
keys results in varying voltages being applied to pin
6, which in turn initiates the various controls.
When operating commands are fed via the remote
control to pin 64 of IC601, pin 6 of IC601 also outputs
a pulse, which feeds transistors Q1102 and Q1107 to
provide a flashing standby LED D1104.
Operating commands issued from the local and
remote control are treated with equal status.
:
Pin 8 - Slow Switching
The circuit is designed so that it is possible to switch
over to AV operation from all programme locations to
the AV interface. The AV 21 pin scart socket JK3102
over to AV operation from all programme locations to
the AV interface. The AV 21 pin scart socket JK3102
allows composite video and RGB signal input. Slow
switching being provided via pin 8 for composite video
input.
switching being provided via pin 8 for composite video
input.
:
Pin 36 - EHT / Short Circuit Protection
This input to the UOC IC which is normally biased by
R2202 and R621, provides protection by switching
the TV into standby mode.
R2202 and R621, provides protection by switching
the TV into standby mode.
Short circuit protection is provided via transistor
Q603. The supply lines which are monitored are:
Q603. The supply lines which are monitored are:
:
+200V supply monitored by D603.
A voltage drop in the +200V supply causes the
voltage across resistor R631 to decrease. This in
turn causes diode D603 to conduct. The base of
Q603 is held high by resistor R622. The voltage
drop applied to the base of transistor Q603,
causes Q603 to switch On. The protection input
at pin 36 of IC601 is now pulled High, switching
the TV into standby.
A voltage drop in the +200V supply causes the
voltage across resistor R631 to decrease. This in
turn causes diode D603 to conduct. The base of
Q603 is held high by resistor R622. The voltage
drop applied to the base of transistor Q603,
causes Q603 to switch On. The protection input
at pin 36 of IC601 is now pulled High, switching
the TV into standby.
:
+5V supply monitored by D601.
A drop in the +5V supply is applied to the base
of transistor Q603, causing the transistor to
switch On. The protection input at pin 36 of IC601
is pulled High, switching the TV into standby.
A drop in the +5V supply is applied to the base
of transistor Q603, causing the transistor to
switch On. The protection input at pin 36 of IC601
is pulled High, switching the TV into standby.
In addition to the supplies mentioned above,
protection is provided for the +8V supply, which is
carried out internally within the UOC IC via pins 14
and 39. When the voltage drops below the
pre-determined reference, the TV is switched into
standby mode.
Protection is also provided for the Automatic Beam
current Limiting (ABL) circuit via D403, discussed in
section 9.1.3.
protection is provided for the +8V supply, which is
carried out internally within the UOC IC via pins 14
and 39. When the voltage drops below the
pre-determined reference, the TV is switched into
standby mode.
Protection is also provided for the Automatic Beam
current Limiting (ABL) circuit via D403, discussed in
section 9.1.3.
:
Pin 49 - Automatic Beam Current Limiting
Beam Current Limiting is performed internally within
the UOC IC IC601, and is used to monitor the voltage
at the BCL terminal pin 49. The brightness and
contrast varies in response to the voltage at pin 49 of
IC601.
The control paths to the BCL input pin 49 is discussed
in the CATS Eye control section 4.1.2. and Colour
Output section 9.1.3.
the UOC IC IC601, and is used to monitor the voltage
at the BCL terminal pin 49. The brightness and
contrast varies in response to the voltage at pin 49 of
IC601.
The control paths to the BCL input pin 49 is discussed
in the CATS Eye control section 4.1.2. and Colour
Output section 9.1.3.
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