JP2964563B2 - Video signal cathode transmission circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial applications]

The present invention relates to a transmission circuit for driving a cathode of a cathode ray tube (CRT).

Summary of the Invention

By terminating the high frequency range of the video output signal on the cathode ray tube socket substrate in RGB monitors, etc., the impedance of the transmission line is matched, and the cathode of the cathode ray tube can be driven in a frequency band exceeding 300 MHz. .

[Prior art and its problems]

For example, in a cathode ray tube display having a video signal frequency characteristic whose operating frequency is up to a 300 MHz band, when the cathode is driven at a high frequency, the stray capacitance of the transmission line and the cathode of the cathode ray tube becomes a problem. Also, since a large current flows in a wideband video drive amplifier, a large heat sink is required, and placing this on a cathode ray tube socket substrate places a burden on the neck of the cathode ray tube,
Difficult to implement. As a conventional example which solves such a problem, as shown in FIG. 2, in a cathode drive circuit for driving a cathode of a cathode ray tube from a cathode output amplifier 1 which is a broadband video signal source, an input terminal, an output terminal and characteristics are shown. First with impedance
A transmission line 2, a second end having an input end, an output end, and a characteristic impedance;
A transmission line 4, a terminating resistor 5 for terminating the output end of the second transmission line 4 with a load matching the characteristic impedance of the second transmission line 4, an output end of the first transmission line 2, a cathode of a cathode ray tube, Impedance matching means 3 for coupling the input end of the second transmission line 4, wherein the impedance matching means 3 sends a signal from the output end of the first transmission line 2 to the cathode, An impedance equal to the characteristic impedance of the first transmission line is connected to the output end of the first transmission line, and an impedance equal to the characteristic impedance of the second transmission line is connected to the input end of the second transmission line. A cathode drive circuit that does not occur. Is known (JP-A-63-69396). In the prior art, the terminating resistor 5 serves as a load (300 MHz) over a wide band and serves as a high-power resistor. In order to increase the size, for example, when a chassis or the like is used as a radiator, in a high-frequency region, As a result, parasitic reactance such as stray capacitance is generated, and high-frequency characteristics are deteriorated.

[Means for solving the problems]

In order to solve the above-mentioned problems, the present invention terminates a high-frequency signal on a cathode ray tube socket board via a high-pass filter, and filters a low-frequency signal on the chassis side. The present invention will be described below with reference to FIG. 1 on the basis that the impedance of the transmission line is matched by terminating the transmission line. In FIG. 1, a signal from a cathode output amplifier 1 which is a broadband video signal source is input from an input terminal A arranged in a chassis 7. Through an inductance L ₁ to form a low-pass wave filter in the input terminal A connected to the load resistance R ₁ of the low-frequency connected to the power supply terminal. Further, a transmission line 6 having a characteristic impedance is connected to the input terminal A, and a cathode line is connected to an output terminal of the transmission line 6 via an impedance matching coil L ₂ mounted on a cathode ray tube (CRT) socket substrate 8. connect the capacitor C ₁ which forms a cathode and high pass filtering instrument tube terminates in a high-frequency load resistor R _2. Also connected between capacitor C ₁ and resistor R ₂ in accordance with the stray capacitance of the resistor R ₂ required a parallel circuit of a resistor R ₃ and the inductance L ₃ in order to compensate.

【Example】

Next, an embodiment of the present invention will be described in detail with reference to FIG. 1. A feeder line having a characteristic impedance of 200Ω is used as a transmission line. The low-frequency load resistance R ₁ and the resistance value of the high frequency load resistance R ₂ and 200 [Omega, further resistor R ₁ is a resistor for a large power,
Resistor R ₂ has a high frequency characteristic to adopt good each resistor for low power. The cut-off frequencies of the low-pass filter and the high-pass filter are set to approximately 10 MHz, and the cut-off points of both filters are crossed over as shown in FIG. The collector or drain of a cathode output amplifier composed of cascade-connected bipolar transistors or field-effect transistors is connected to the input terminal A. As shown in Fig. 4, CR
Bifilar coil L ₂ (pattern width 100 μm, pattern interval 1)
00 μm). Furthermore, it can be simultaneously formed by the same etching method and the compensation inductance L ₃ also bifilar coil L _2. Condenser C ₁ and compensating resistor R ₃ to form a high-pass filtering unit are both wires connect the chip component to the solder dipping side of the CRT socket substrate, the connection between the feeder line and the impedance matching coil L _2, a high frequency load resistance And the compensation circuit are also connected on the solder dip side.

[Effects]

Since the present invention is configured as described above, when viewed from the input terminal A, it appears that the terminal is equivalently terminated with a pure resistance of 200Ω from DC to high frequency, and impedance matching can be realized over a wide band. Is the load impedance of the video output stage amplifier, so that the video output stage amplifier can obtain a stable gain over a wide band. Further, since power is consumed most of a low-pass wave filter cutoff frequency lower than the frequency of the terminating resistor R _1, the terminating resistor R ₂ frequencies higher than the cut-off frequency of the high-pass filtering instrument small corner with a small resistor for power, it is possible to installed near the cathode on a cathode ray tube socket substrate 8, the high frequency characteristic is not degraded even by using the chassis 7 as a heat radiator of the terminating resistor R ₁ . Furthermore, a high-power resistor with high-frequency characteristics is expensive, but the present invention requires a low-frequency load resistor with low power,
It leads to cost reduction.

[Brief description of the drawings]

1 is a circuit diagram of the present invention, FIG. 2 is a circuit diagram of a conventional example, FIG. 3 is a crossover characteristic diagram of a filter, and FIG. 4 is a plan view of a cathode ray tube (CRT) socket substrate. FIG. 1. Broadband video signal source, 2, 4, 6 ... Transmission line,
3 ... impedance matching means, 5 ... terminating resistor, 7 ...
… Chassis, 8… Cathode tube (CRT) socket board, R ₁
…… Load resistor for low frequency, R ₂ …… Load resistor for high frequency, L ₁ …
… Inductance forming low-pass filter, L ₂ …… Impedance matching coil, C ₁ … Capacitor forming high-pass filter, R ₃ …… Compensation resistance, L ₃ …… Compensation inductance

Claims (1)

(57) [Claims] An input terminal of a transmission line to which a video signal is applied is connected to a low-frequency load resistor via a low-pass filter, and an output terminal is provided with an impedance matching circuit and a high-pass filter. A cathode-ray tube driving circuit, wherein a high-frequency load resistor is connected via the high-frequency amplifier and a video output signal from the impedance matching circuit is applied to the cathode-ray tube.