JPH0516772Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a horizontal deflection circuit for deflecting an electron beam left and right by passing a sawtooth current through the horizontal deflection coil of a CRT.

[Problems to be solved by conventional techniques and ideas]

In general, a horizontal deflection circuit consists of a horizontal AFC circuit that automatically controls the oscillation frequency and phase to follow an input horizontal synchronization signal, a VCO that is controlled by the output of the horizontal AFC circuit, and a VCO that controls the oscillation voltage of the VCO sufficiently. It consists of a horizontal drive circuit for amplification and a horizontal output circuit for supplying deflection current to the horizontal deflection coil.

Figure 2 shows a specific circuit example of a horizontal drive circuit and a horizontal output circuit in a conventional horizontal deflection circuit.
The horizontal drive circuit 3 is configured as a transformer-coupled amplifier circuit with a grounded emitter.
transistor 3a is applied to its base
It is turned on and off by pulses from VCO2.
When the transistor 3a is turned on, the transistor 4 of the horizontal output circuit 4 coupled via the transformer T is turned on.
A base current flows to the base of transistor 4
a turns on. Due to this, a current flows from the + power supply to the ground through the horizontal deflection coil L _H and the transistor 4a. After that, the transistor 4a is turned off, but the current charging the capacitor C due to the back electromotive force continues to flow in the same direction through the coil _LH .
When this charging current becomes 0, the discharging current of the capacitor C flows in the opposite direction to the coil L _H , and the discharge ends thereafter, but the current due to the reverse starting force flows in the same direction through the damper diode D to the coil L _H. continue. Therefore, a sawtooth wave current as shown in FIG. 3B is caused to flow through the horizontal deflection coil L _H in response to the application of the base voltage shown in FIG. 3A to the transistor 4a.

By the way, some recent television receivers are now compatible with video signals in which the number of scanning lines in one field has been changed to 525, twice that of a normal receiver, in order to obtain higher quality images. There is a so-called multi-scan method. In this type of multi-scan type receiver, the transistor 4a of the horizontal output circuit 4 is turned on and off by a pulse of 15.75 KHz, which is equal to the frequency _H of the horizontal synchronizing signal when the signal is a normal video signal, and when the number of scanning lines is twice as high. is turned on and off by a 31.5 KHz pulse, but in the conventional horizontal deflection circuit described above, it was not possible to always drive the transistor 4a of the horizontal output circuit in an optimal state depending on the number of scanning lines.

In other words, even if a pulse voltage as shown in Fig. 4a is applied to the base of a transistor that generally functions as a switching element, the collector current is
As shown in Figure b, the maximum current does not reach the maximum current at the same time as the pulse voltage rises, but is delayed by a certain period of time _td . Further, even if the pulse voltage is set to 0, the collector current does not become 0 at the same time as the pulse voltage falls; the maximum collector current continues to flow for the storage time _ts , and then gradually becomes 0 over the fall time _tf . As shown in Figure 4c, a base current I _B1 flows through the base at the same time as the pulse voltage rises, and a base current I _B2 in the opposite direction to I _B1 flows at the same time as the pulse voltage _{falls .} Only time passes.

The above time t _s + t _f is called turn-off time,
Affects the frequency at which the transistor is switched. Therefore, a high switching frequency
When operating at _H , it is desirable to operate the transistor in a non-saturation region rather than in a saturation region, so that the storage time _ts becomes small.

Note that the loss of a transistor depends on the internal resistance of the transistor when the collector current is flowing, and is almost negligible when operating in the saturated region, and increases when operating in the non-saturated region.
Furthermore, when the transistor is switched at a high frequency, the ratio of the turn-off time to the on-period becomes relatively long. For this reason, in conventional multi-scan television receivers,
The horizontal drive circuit 3 was set so that base currents i _B1 and t _B2 flow such that the drive state of the horizontal output circuit is optimal when the number of scanning lines, that is, the deflection frequency is large.

However, when the drive state is set in this way, when the number of scanning lines, that is, the deflection frequency becomes small, and the on-period of the transistor becomes long and the turn period occupied in this period becomes relatively short, the on-period becomes non-saturated. A problem arises in that the loss due to operation in the area is greater than normal.

Therefore, an object of the present invention is to provide a horizontal deflection circuit that can always maintain an optimal drive state even when the deflection frequency changes, and can also minimize the loss of transistors in the horizontal output circuit. There is.

[Means and actions to solve the problem]

In order to solve the above problems, the horizontal deflection circuit according to the present invention is characterized by having a constant current circuit that supplies a current inversely proportional to the frequency of the horizontal synchronization signal to the transistor of the horizontal drive circuit.

Since the constant current circuit supplies a small current to the horizontal drive circuit when the frequency of the horizontal synchronization signal, that is, the deflection frequency is large, the base current flowing from the horizontal drive circuit to the base of the transistor of the horizontal output circuit becomes small, and the horizontal output The transistors of the circuit are now operated in a non-saturated state. On the other hand, when the frequency of the horizontal synchronization signal, that is, the deflection frequency, is small, a large current is supplied to the horizontal drive circuit, so the base current flowing from the horizontal drive circuit to the base of the transistor of the horizontal output circuit becomes large. The transistors of the horizontal output circuit are operated in the saturation region.

〔Example〕

Hereinafter, embodiments of the present invention will be described based on the drawings.

FIG. 1 is a circuit diagram showing an embodiment of the horizontal deflection circuit according to the present invention, in which reference numeral 11 denotes a synchronization separation circuit that separates and outputs a horizontal synchronization signal from a video signal;
2 is a VCO whose oscillation frequency is controlled by voltage; 13 is a VCO whose oscillation frequency is controlled by voltage;
The oscillation frequency and phase of VCO12 are synchronized with the separation circuit 1
14 is a horizontal drive circuit that sufficiently amplifies the oscillation voltage of VCO 12, and 14 is a horizontal drive circuit that sufficiently amplifies the oscillation voltage of VCO 2. switching transistor 14
It has a. The emitter of the transistor 14a is connected to ground, and the collector is connected to one of the coupling transformers T.
It is connected to the constant current circuit 15 via the next winding _L1 .

The emitter of the constant current circuit 15 is the current limiting resistor 15.
The collector is connected to the + power supply through a to the connected transformer T.
and PNP transistors 15b each connected to the collector of the transistor 14a of the horizontal drive circuit 14 through the primary winding _L1 of the
The base of the transistor 15b is connected to the output of an fV conversion circuit 16 that outputs a voltage according to the frequency of the horizontal synchronization signal from the frequency separation circuit 11.

The secondary winding L ₂ of the coupling transformer T is connected to the horizontal output circuit 17 . The horizontal output circuit 17 has a switching transistor 17a whose base is connected to the secondary winding _L2 of the coupling transformer T, whose emitter is connected to ground, and whose collector is connected to the + power supply via the horizontal deflection coil _LH . transistor 17
A damper diode 18 is connected between the emitter and collector of a, and the horizontal deflection coil _LH is connected to the
A charging/discharging capacitor 19 is connected in parallel.
Note that 20 is a bypass capacitor connected between the collector of the transistor 15b of the constant current circuit 15 and the ground.

In the above configuration, the f-V conversion circuit 16 is
When the frequency of the horizontal synchronizing signal separated by the period separation circuit 11 is 15.75 KHz during normal scan, a smaller voltage is output compared to 31.5 KHz during double scan, and this is used as the base of constant current circuit 15. Apply. Therefore, the transistor 15b of the constant current circuit 15 normally draws a large current during scan.
During double scan, a small current is supplied to each horizontal drive circuit 14.

As mentioned above, a constant current whose magnitude is inversely proportional to the frequency of the horizontal synchronizing signal is supplied from the constant current circuit 15 to the horizontal drive circuit 14, so that it oscillates at a frequency equal to the frequency of the horizontal synchronizing signal.
The transistor 14a of the horizontal drive circuit 14, to which the oscillation voltage of the VCO 13 is applied to the base,
The current that flows when it is turned on becomes inversely proportional to the frequency of the horizontal synchronizing signal. Therefore, when the current flowing through the transistor 14a of the horizontal drive circuit 14 is small, that is, when the frequency of the horizontal synchronizing signal is high in double scan, the base current flowing through the coupling transformer T to the base of the transistor 17a of the horizontal output circuit 17 is small. (Figure 4, i _B1 and i _B2 )
becomes smaller, the transistor 17a is turned on in a non-saturated state, and the turn-off time is shortened. On the other hand, when the current flowing through the transistor 14a of the horizontal drive circuit 14 is large, that is, during normal scan in which the frequency of the horizontal synchronizing signal is low, the base current (fourth figure,
i _B1 and i _B2 ) become large, and transistor 17a
is turned on in the saturated region.

In this way, the transistor 1 of the horizontal output circuit 17
By changing the drive state of 7a according to the frequency of the horizontal synchronizing signal, the horizontal output circuit 17 can always be operated in an optimal state with less loss.

〔effect〕

As explained above, according to the present invention, the current supplied to the transistor of the horizontal drive circuit is changed in inverse proportion to the frequency of the horizontal synchronization signal, so that the drive state of the transistor of the horizontal output circuit is changed when the frequency is high. It is now possible to operate in the non-saturation region and in the saturated region when the temperature is low, and it is possible to always maintain the optimum drive state and to minimize the loss of the transistors in the horizontal output circuit.

[Brief explanation of the drawing]

Fig. 1 is a circuit diagram showing an example of a horizontal deflection circuit according to the present invention, Fig. 2 is a circuit diagram showing an example of a conventional horizontal deflection circuit, and Fig. 3 shows waveforms of various parts in the circuit of Fig. 2. FIG. 4 is a waveform diagram for explaining the operation of the switching transistor. 11...Synchronization separation circuit, 12...VCO, 13
...Horizontal AFC circuit, 14...Horizontal drive circuit,
14a...transistor, 15...constant current circuit,
17...Horizontal output circuit, 17a...Transistor, L _H ...Horizontal deflection coil.

Claims (1)

[Claims for Utility Model Registration] A horizontal oscillation circuit, a horizontal AFC circuit that automatically controls the oscillation frequency and phase of the horizontal oscillation circuit to follow a horizontal synchronization signal, and a horizontal AFC circuit that amplifies the oscillation voltage of the horizontal oscillation circuit. A horizontal deflection circuit having a drive circuit and a horizontal output circuit having a transistor that is turned on and off by an output of the horizontal drive circuit to supply a deflection current to a horizontal deflection coil, wherein a horizontal synchronizing signal is applied to the transistor of the horizontal drive circuit. A horizontal deflection circuit characterized by having a constant current circuit that supplies a current inversely proportional to frequency.