Television fault detection and protection apparatus

A phase-lock-loop circuit of a deflection apparatus generates a first signal at the horizontal frequency during normal operation. The first signal is coupled to a phase-control-loop circuit that maintains the deflection current timing in phase with the first signal. A fault protection circuit disables the generation of signal transitions in the first signal when a fault condition occurs. A circuit that detects the presence of transition edges in the first signal prevents the operation of the deflection output stage when the transition edges in the first signal are missing.

The invention relates to an arrangement for protecting a television 
apparatus such as, for example, an x-ray protection circuit. 
BACKGROUND OF THE INVENTION 
A typical deflection circuit in a television receiver includes an output 
stage that generates a deflection current in a deflection winding and that 
generates retrace pulses used for generating an ultor voltage. The output 
stage is controlled by a horizontal rate switching control signal. 
Timing of the deflection current produced by the horizontal deflection 
circuit output stage may vary in a manner dependent upon loading of the 
ultor voltage source. For example, such loading may be dependent upon the 
brightness of the image being displayed on a kinescope of the receiver. 
Variation in such loading causes, for example, a corresponding variation 
in a delay of the horizontal retrace pulses and of the deflection current. 
Furthermore, disadvantageously, it may cause a distortion of the image 
being displayed. 
A circuit embodying the invention includes a dual feedback loop arrangement 
that is used for preventing the occurrence of the variation in the delay 
of the deflection current relative to, for example, a horizontal 
synchronizing signal. In such arrangement, a horizontal oscillator 
generates a signal at, for example, a frequency greater than the 
horizontal frequency. The oscillator generated signal is divided down in a 
frequency divider and a first output signal that is at or near the 
horizontal frequency is generated. The oscillator, frequency divider and a 
first phase detector are included in a phase-lock-loop circuit (PLL) that 
is synchronized by the horizontal synchronizing signal that is obtained, 
for example, from a sync separator of the television receiver. 
The PLL, having a relatively long time constant, controls the oscillator to 
maintain the first output signal in frequency and phase synchronism with 
the horizontal synchronizing signal. 
In order to compensate for such load dependent variations in the delay 
associated with the horizontal deflection circuit output stage, a 
phase-control-loop circuit (PCL) is used. The PCL includes a second phase 
detector, a first input terminal of which is coupled to the first output 
signal of the PLL and a second input terminal of which is coupled to the 
deflection circuit output stage for responding to the retrace pulse 
generated by the output stage. The phase detector produces a phase 
difference indicative signal from the signals at the first and second 
input terminals. A low-pass, loop filter generates a control signal from 
the phase difference indicative signal. A phase shifting arrangement that 
is responsive to the control signal produces a horizontal-rate output 
signal having pulses at the horizontal rate and at a variable delay which 
makes, for example, the retrace pulses synchronous with the horizontal 
synchronizing signal even when variations of beam current loading occur. 
The PLL may be internal to an integrated circuit (IC) such as, for example, 
TA 7777 that is made by Toshiba Co. (the Toshiba IC). The Toshiba IC 
produces, at corresponding output terminals, the first output signal at 
the horizontal frequency and the aforementioned second output signal at 
the frequency that is greater than the horizontal frequency and that is 
synchronized to the first output signal. 
In a typical television display system, the high voltage ultor accelerating 
potential is applied to the final anode electrode of a picture tube to 
accelerate an electron beam generated at a picture tube cathode onto a 
phosphor screen. To ensure that the television receiver will not be 
operated, under a fault condition, at excessive ultor potential level, a 
high voltage protection circuit is incorporated in the television receiver 
circuitry. Thus, for example, the Toshiba IC includes such high voltage 
protection circuit. An excessive ultor potential level, for example, will 
disable, in the Toshiba IC, the generation of the horizontal rate first 
output signal, but not of the second output signal at the frequency that 
is greater than the horizontal frequency. 
The PCL that, in a circuit embodying the invention, may be internal to a 
second IC, is constructed in such a way that it utilizes the second output 
signal of the PLL of the Toshiba IC that is at the frequency that is 
greater than the horizontal frequency for its internal operation. 
Utilization of the second output signal, advantageously, simplifies the 
design of the PCL. The output signal of the PCL that is synchronized to 
the first output signal of the PLL controls the switching timing in the 
deflection circuit output stage. 
When the Toshiba IC is used to provide the PLL operation that was described 
before, the output signal of the PCL may be generated as a result of the 
presence of the second output signal at the greater frequency even when 
the first output signal, as a result of the fault condition, is disabled. 
Disadvantageously, the fault protection circuit of the Toshiba IC, by 
itself, will not prevent the generation of the output signal of the PCL 
and, hence, will not prevent the generation of the ultor voltage. 
In accordance with an aspect of the invention, recurring signal transitions 
in the first output signal are detected. When no recurring signal 
transitions occur, that is indicative of the fault condition, a detection 
circuitry that detects such signal transitions disables the generation of 
the output signal of the PCL and thereby prevents the generation of the 
ultor voltage. 
SUMMARY OF THE INVENTION 
In accordance with another aspect of the invention, a television apparatus 
power supply with a fault protection arrangement includes a source of an 
input signal at a frequency that is related to a deflection frequency. A 
fault indicative signal is generated when a fault condition occurs in the 
power supply. A first signal is generated at a first terminal during 
normal operation having transition edges at a frequency that is related to 
that of the input signal. When the fault indicative signal is generated, 
the occurrence of the transition edges of the first signal is prevented. A 
second signal is generated at a second terminal, both during normal 
operation and when the fault indicative signal occurs, at a frequency that 
is related to that of the input signal. A third signal is generated when a 
transition edge within the first signal is missing. Switching means, 
switching in response to the second signal and coupled to a load and to a 
source of input supply voltage develops an output supply voltage for the 
load during normal operation. The third signal prevents the occurrence of 
the switching operation that substantially reduces the output supply 
voltage when the third signal is generated.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
Horizontal sync pulses S.sub.H of FIG. 1 having a period H, that in NTSC is 
63.5 microseconds, and having a corresponding frequency f.sub.H are 
coupled, illustratively, from a conventional sync separator of a 
television receiver, not shown in the figure, to an input terminal 30a of 
a phase detector 30. A signal O'.sub.H that, as described later on, at 
steady state operation, is at the frequency f.sub.H, is coupled via a 
"NAND" gate 300 and a capacitor C.sub.c to a second input terminal 30b of 
phase detector 30. A phase difference indicative signal PH that is 
indicative of the phase difference between signal S.sub.H and signal 
O'.sub.H is coupled to a frequency control input terminal 31a of a voltage 
controlled oscillator 31. Oscillator 31 generates an output signal 
O.sub.32H at a frequency 32xf.sub.H. Signal O.sub.32H is frequency divided 
by 32 in a frequency divider 32 to produce signal O+H Thus, detector 30, 
oscillator 31 and frequency divider 32 form a phase-lock-loop circuit 
(PLL) 20 that may be included in a first integrated circuit 100 and its 
externally located associated circuitry such as, for example, capacitor 
C.sub.c. The operation of PLL 20 causes a corresponding transition edge in 
a corresponding period of each of signals O.sub.H and O.sub.32H to be in 
phase with that of signal S.sub.H. 
A phase-control-loop (PCL) 30, having a control section that may be 
internal to a second integrated circuit 200, generates a signal D.sub.H at 
the frequency f.sub.H, as described later on. Signal D.sub.H is coupled to 
a horizontal driver 33 that generates a drive signal 33a that is coupled 
to a base electrode of a switching transistor Q1 of, for example, a 
conventional horizontal output stage 99. Output stage 99 produces, in a 
winding 34 of a flyback transformer T0, a retrace pulse at a high voltage 
that is used, in a high voltage supply 35 for generating an ultor voltage 
U. Voltage U is coupled to an ultor electrode of a cathode ray tube of the 
television receiver, not shown in the FIGURES. 
During normal operation, signal O.sub.H ' is coupled via "NAND" gate 300 
that is enabled to form a corresponding signal O.sub.H at a terminal 300a. 
PCL 30 is synchronized to signal O.sub.H in such a way that deflection 
current i.sub.Y in a deflection winding L.sub.Y is maintained during 
normal operation in a corresponding constant phase relationship relative 
to signal O.sub.H despite varying beam current loading that loads winding 
34, as described in detail later on. 
IC 200 that includes the control section of PCL 30 includes a flip-flop 40 
having a clock receiving terminal 40a that receives signal O.sub.32H that 
is at the frequency 32xf.sub.H. Flip-flop 40 generates an output signal 
E.sub.16H that toggles, or changes states, each time a clocking edge of 
signal O.sub.32H occurs. Signal E.sub.16H is at a frequency 16xf.sub.H 
that is one-half of the frequency of signal O.sub.32H. Flip-flop 40 forms 
the first stage in a five-stage cascaded-coupled frequency dividing 
arrangement 45 that includes flip-flops 40-44. Arrangement 45 generates 
corresponding output signals E.sub.16H, E.sub.8H, E.sub.4H, E.sub.2H and 
E.sub.H at frequencies 16xf.sub.H, 8xf.sub.H, 4xf.sub.H, 2xf.sub.H and 
f.sub.H, respectively, at corresponding output terminals of flip-flops 
40-44. Signal O.sub.H is coupled via an "AND" gate 52 to a corresponding 
reset pulse receiving terminal RESET of each of flip-fops 40-44 for 
insuring a predetermined phase relationship between each of signals 
E.sub.16H, E.sub.8H, E.sub.4H, E.sub.2H and E.sub.H and of signal O.sub.H. 
Each of flip-flops 40-44 assumes a FALSE state when a leading edge 
O.sub.Ha of signal O.sub.H occurs. A flip-flop 51 delays signal O.sub.H by 
approximately one microsecond to form a delayed signal 51a that is 
inverted relative to signal O.sub.H. The one microsecond delay time is 
caused by the relative timings between a corresponding clocking edge 
signal O.sub.32H that is coupled to a clock receiving terminal of 
flip-flop 51 and a corresponding transition edge of signal O.sub.H. 
Delayed signal 51a that is coupled to an input terminal 52a of "AND" gate 
52 disables gate 52 one microsecond after leading edge O.sub.Ha of signal 
O.sub.H occurs. Thus, a pulse 50 is generated on a conductor 49 when both 
signals 51a and O.sub.H are simultaneously at corresponding TRUE states. 
Pulse 50 that has a duration of approximately one microsecond and that is 
at the horizontal rate f.sub.H is synchronized to signal O.sub.H. 
When pulse 50 occurs, each of flip-flops 40-44 is initialized to provide 
the corresponding output signal at a corresponding predetermined state 
such as, for example, a FALSE state. Thus, each of the output signals of 
flip-flops 40-44 is also periodic at the frequency f.sub.H of signal 
O.sub.H or 50. If no significant phase perturbation in signals O.sub.H and 
O.sub.32H of PLL 20 occurs, after being initialized by signal 50, each of 
the corresponding output signals of flip-flops 40-44 will remain, in each 
subsequent period H, in a corresponding constant phase relationship with 
respect to signal 0.sub.H. 
Signals E.sub.16H, E.sub.8H, E.sub.4H, E.sub.2H and E.sub.H that are 
synchronized to signal O.sub.H are used to provide timing signals that are 
required for the operation of IC 200 at corresponding predetermined 
instants that occur during each period H of signal O.sub.H. The timing 
resolution by which each of such timing pulse is formed is determined by 
the period of signal O.sub.32H. A signal 36 is an example of such timing 
pulses. Signal 36 that is used, as described later on, for operating PCL 
30 is a horizontal rate signal that is produced at an output terminal 53a 
of a flip-flop 53. 
To generate signal 36, signals E.sub.4H, E.sub.2H and E.sub.H are coupled 
to corresponding input terminals of an "AND" gate 54, that produces a 
signal 54a having the TRUE state when each of such input signals is at the 
TRUE state simultaneously with the other ones. Signal 54a is coupled to a 
data input receiving terminal 53c of a flip-flop 53. Signal E.sub.8H is 
coupled to a clock input receiving terminal 53b of flip-flop 53. Flip-flop 
53 delays signal 54a by an interval having a duration that is determined 
by signal E8H to form signal 36. Signal 36 is at the TRUE state during 
approximately 8 microseconds and at the FALSE state during the rest of 
period H. Thus, signal 36 is delayed relative to signal O.sub.H by a 
predetermined delay that is determined by signals E.sub.8H, E.sub.4H, 
E.sub.2H and E.sub.H. Signal 36 is used for controlling the timing of a 
ramp generator 37 of IC 200 that is used by PCL 30, as described below. 
Ramp generator 37 generates a sawtooth signal 37a that is coupled to an 
input terminal 38a of a voltage comparator 38. Generator 37 includes a 
current source ics that is coupled to a capacitor C.sub.37 that is, for 
example, located externally to IC 200. A switch 37b of generator 37 is 
coupled across capacitor C.sub.37 for discharging capacitor C.sub.37 and 
for maintaining, afterward, sawtooth signal 37a across capacitor C.sub.37 
at a constant level as long as horizontal rate control signal 36 is at the 
TRUE state. When signal 36 is at the FALSE state, current source i.sub.cs 
charges capacitor C.sub.37 to form an upramping portion 37c of signal 37a. 
Signal O.sub.H is also coupled via a flip-flop 39 to an input terminal 57a 
of a second phase detector 57. Flip-flop 39 is clocked by signal E.sub.8H 
to provide a delayed signal 39a that is delayed relative to signal O.sub.H 
by approximately 4 microseconds. The purpose of the 4 microsecond delay is 
to compensate for various delays in PLL 30. A signal F.sub.H, developed in 
a winding 136 of flyback transformer T0, is coupled via a delay and pulse 
shaping network 58 to a second input terminal 57b of phase detector 57. 
Signal F.sub.H is indicative of the phase of deflection current i.sub.y in 
deflection winding L.sub.Y. An output signal 59 of phase detector 57 that 
is indicative of the phase difference between signal 39a and signal 
F.sub.H is coupled via a low-pass filter 66 to form a phase control signal 
66a at a second input terminal 38b of comparator 38. 
When, during a given period H, ramping portion 37b of signal 37a becomes 
greater than signal 66a at terminal 38b of comparator 38, comparator 38 
generates a transition edge of a signal 60 that is coupled to a trigger 
receiving input terminal 61a of a one-shot flip-flop 61. Consequently, 
flip-flop 61 generates a pulse D.sub.Ha having, illustratively, a constant 
duration. Pulse D.sub.Ha is coupled, during normal operation, via a 
transistor Q2 to form signal D.sub.H. Signal D.sub.H at the collector of 
transistor Q2 is coupled to horizontal driver 33. Pulse D.sub.Ha of signal 
D.sub.H causes transistor Q1 to be conductive. During normal operation, 
pulse D.sub.Ha occurs, relative to signal O.sub.H, after an interval 
having a variable duration that is controllable in accordance with phase 
control signal 66a of filter 66. A change in the ultor loading at a 
terminal 35a of high voltage supply 35 that tends to cause a change in the 
phase of signal F.sub.H, will cause a corresponding change in the delay of 
signal D.sub.H in a negative feedback manner that will maintain constant 
the phase of signal F.sub.H and that of deflection current i.sub.y 
relative to signal O.sub.H, despite varying ultor loading. 
IC 100 includes a well known high voltage protection circuit 301 responsive 
to a signal OV that is proportional to ultor voltage U, that prevents 
signal O.sub.H from changing states when a fault condition occurs. The 
fault condition occurs, for example, when ultor voltage U exceeds a 
predetermined permitted level. When such fault condition occurs, circuit 
301 generates an inhibit signal 301a. Signal 301a that is coupled to an 
input terminal of "NAND" gate 300 causes signal O.sub.H to remain at a 
disabled or TRUE state as long as signal 301a is generated. Therefore, 
signal transitions in signal O.sub.H are prevented when the fault 
condition occurs. 
On the other hand, signal O.sub.32H is generated even when the fault 
condition occurs. As a result of the operation of frequency dividing 
arrangement 45, ramp generator 37, comparator 38 and flip-flop 61, pulses 
D.sub.Ha will be generated at an output terminal 61a of one shot flip-flop 
61 even when signal O.sub.H is disabled. Pulse D.sub.Ha will continue to 
be generated because, when signal O.sub.H remains at the TRUE state 
indefinitely, signal 66a of low-pass-filter 66a is less positive than the 
peak of signal 37a that will enable the generation of pulses D.sub.Ha. 
In accordance with an aspect of the invention, pulses D.sub.Ha that are 
coupled to the base electrode of transistor Q2 through a resistor 302 are 
prevented from causing the generation of signal D.sub.H, when ultor 
voltage U exceeded the predetermined permitted level. In carrying out such 
aspect of the invention, a flip-flop 303 is used for detecting the 
presence of pulses in signal O.sub.H. When signal O.sub.H is at the 
disabled state because of, for example, the disabling operation of 
protection circuit 301, flip-flop 303, as described below, maintains 
transistor Q2 at a nonconductive state as long as, for example, generation 
of signal transitions in signal O.sub.H are prevented. Consequently, the 
generation of signal D.sub.H and of ultor voltage U are, advantageously, 
also prevented. 
FIGS. 2a-2f illustrate timing diagrams that are useful in explaining the 
operation of a protection arrangement 333 that includes flip-flop 303 and 
transistor Q3 of FIG. 1. Arrangement 333 maintains transistor Q2 
nonconductive as long as signal transitions in signal O.sub.H are 
prevented. Similar numbers and symbols in FIGS. 1 and 2a-2f indicate 
similar items or functions. 
Flip-flop 303 of FIG. 1 that is of the RESET-SET (R-S) type, has a terminal 
303b that is coupled to a signal 306a. Signal 306a is generated by an 
"AND" gate 306, an "AND" gate 305 and "AND" gate 54 when all of signals 
E.sub.H, E.sub.2H, E.sub.4H, E.sub.8H and E.sub.16H are, each, at a 
corresponding TRUE state. Thus, signal 306a of FIG. 2c is generated during 
an interval t.sub.1 -t.sub.3 of signal O.sub.32H of FIG. 2a that, in 
normal operation, occurs immediately prior to leading edge O.sub.Ha of 
signal O.sub.H of FIG. 2b. As a result of signal 306a of FIG. 1, flip-flop 
303 is set at time t.sub.2 of FIG. 2c, causing an output signal 303a to be 
generated at a TRUE state immediately after time t.sub.2 of FIG. 2e. 
Signal 50 that, as described before, initializes arrangement 45, is also 
coupled to a reset terminal 303c of flip-flop 303. During normal 
operation, signal 50 of FIG. 2d occurs, at time t.sub.3, immediately after 
edge O.sub.Ha of FIG. 2b at time t.sub.3. Consequently, during normal 
operation, flip-flop 303 of FIG. 1 is reset and signal 303a of FIG. 2e 
returns to the FALSE state immediately after time t.sub.3. 
During normal operation, pulse D.sub.Ha has a falling edge at a time 
t.sub.1 of FIG. 2f, that occurs approximately 5 microseconds prior to time 
t.sub.2 of FIG. 2e. Time t.sub.2 occurs, as described before, when signal 
303a of flip-flop 303 of FIG. 1 changes states. Pulse D.sub.Ha has a 
rising edge at a time t.sub.4 of FIG. 2f, that occurs approximately 18 
microseconds after time t.sub.3 of FIG. 2e. Thus, during normal operation, 
the duration of pulse D.sub.Ha of FIG. 2f overlaps that of signal 303a of 
FIG. 2e. 
At its TRUE state, signal 303a, that is coupled to the base electrode of a 
transistor Q3 of FIG. 1, causes transistor Q3 to operate as a conductive 
switch. When conductive, transistor Q3 forms a low impedance between the 
base electrode of transistor Q2 and ground that maintains transistor Q2 
nonconductive. 
During normal operation, pulse D.sub.Ha of FIG. 2.sub.f maintains 
transistor Q2 of FIG. 1 nonconductive that maintains transistor Q1 
oonductive throughout interval t.sub.1 -t.sub.4 of FIG. 2f. Consequently, 
during normal operation, signal 303a of FIG. 1 has no effect on the 
conduction of transistors Q2 and Q1. 
In carrying out a further aspect of the invention, when, as a result of 
excessive ultor voltage, for example, signal O.sub.H remains indefinitely 
at the TRUE state, signal 51a of flip-flop 51 remains at the FALSE state. 
The FALSE state of signal 51a prevents the generation of signal 50 of FIG. 
2d at the TRUE state, as shown by the dashed line. Consequently, signal 
303a of FIG. 2e remains, after the fault condition occurs, at the TRUE 
state for an indefinite duration, as shown by the dashed line in FIG. 2e. 
When the fault condition occurs, signal 303a that remains at the TRUE state 
indefinitely maintains transistor Q2 nonconductive. The result is that, 
advantageously, transistor Q1 is maintained in cutoff and is prevented 
from performing its switching operation; therefore, ultor voltage U 
becomes zero. 
Thus, in carrying out another aspect of the invention, signal 303a of 
flip-flop 303 disables high voltage supply 35 when, as a result of the 
fault condition, high voltage protection circuit 301 prevents the 
generation of transition edges in signal 0.sub.H.