TH4793B - Cycle for vertical deflection - Google Patents

Abstract

The vertical deflection amplifiers (20) of the video display will consist of the first (chemical letter 1) and second transmitter output sectors. (Chemistry letter 2) is classified as a toten-pole and push-plu. The coils for vertical deflection (Lv) are connected to the output sector at the output terminal. (22) of the s-capacitor amplification amplifier (C1) is connected to the deflection coil (Lv) at the second terminal (21) far from the terminal. Output (22), source (23), signal that determines the deflection rate, is connected to the deflection amplifier (20) to generate the deflection current (iv) in the coil for Deviation (Lv) The base current generator (40) is connected to the output sector of the first amplifier transistor (chemical letter 1) to obtain the base current (1) at the point. The capacitor voltage (v1) is then fed to the base current generator (40) to enable the base current (i1) to be carried in the output sector of the first amplifier ( Chemistry letter 1) When the video display is switched on for the first time, the discharged s-capacitor (C1) is initially discharged slowly from the good supply. Voltage stage (+ 30v) to extend the The vertical deflection occurs after the tube has released the magnetic field.

Claims (9)

1. The deviation circuit consists of The deflection amplifier consists of the first and second transistor output sectors. The deflection coils for further diverting to the first and second transistor amplifier output sectors mentioned at the deflection amplifier output terminals. The S-shaped capacitor is connected to the aforementioned deflection coil at the second terminal far from the amplifier's output terminal to obtain s-. Capacitors Voltages The signal source, which determines the deflection, is connected to the aforementioned deflection amplifier to produce a flattening current of the said deflection coil. Section which is connected to the aforementioned displacement amplifiers and the response to a voltage that replaces the aforementioned s-capacitor voltages to produce a feedback loop. Flat wind of DC current to stabilize the DC volt stage at the aforementioned output terminals. The base current generator is connected to the output sector of the aforementioned amplifier amplifier to obtain the said current of the base current. The base current generating circuit is then continued. To the terminal Two of the above-mentioned s-capacitors and voltages are fed to that polarity independent of the DC negative feedback loop to enable the conduction of the base current. 2. The displacement circuit corresponding to claim 1 includes a DC voltage stage supply and contributes to the aforementioned s-capacitor charge from the source from the DC voltage stage. Has a charge that is higher than a predetermined size 3. The deflection circuit, corresponding to claim No. 2, in which the conduction of the aforementioned base currents becomes desirable when the aforementioned s-capacitor voltage has The value is lower than the specified voltage scale. 4. The deflection circuit complies with Clause 3, where the rate of s-capacitor from the aforementioned DC voltage supply is not sufficiently low to cause Prolongation of time to reach a predetermined size of charge to hold the scan current generation time during the start-up period. 5. The deflection circuit complies with Clause 2 in which the aforementioned charge segment generates a charge current which is shorted through the deflection coil. 6. The displacement circuit corresponding to claim No. 5, in which the aforementioned charge segment generates the aforementioned charge current, which is shorted through the region's primary current path. The output of the first transistor amplifier. 7. The displacement circuit complies with claim No. 2, where the base current generation segment includes a controllable semiconductor input that responds to s-capacitors. The aforementioned voltages to control the conductivity of the aforementioned base currents in accordance with the s-capacitor voltages. 8. The deflection circuit complies with claim No. 2, in which the said deflection current is charged to the s-capacitor at each cyclone of the deflection through the output sector of The first transistor amplifier mentioned and discharged of the said s-capacitor through other sectors. 9. The deflection circuit complies with Clause 8 in which the output sectors of the 2 transistor amplifier are assembled into a tetem-pole shape. ) 1 0. Circuit for the deflection corresponding to Clause 9, in which the aforementioned base current generator circuit will include a boot-capacitor coupled to the transistor output sector. One of the amplifiers mentioned and the part that will respond to the voltage of the s-capacitor to the boot-capacitor charge of the said s-capacitor. And then during the time within the latter part of each cycle of turn 1 1. A circuit that complies with Clause 10, in which the aforementioned boot-capacitor capacitor portion includes the part for the voltage input of the said s-capacitor to The bootstrap capacitor already mentioned via rectifier 1. 2. The deviation cycle consists of Coil for deflection s-capacitors are connected to the deflection coils described in a series deflection manner. The source of the voltage source The amplifiers for divergence include the first and second output sectors connected between the said source and the point of the first and second output phase reference voltage. As mentioned above, they are connected together and further to the series deflection characteristics at the output terminals of the deflection amplifiers to form a push-pool shape which will charge s- Capacitors mentioned from The source said through the first output sector mentioned and it discharges the said s-capacitor via the said second output sector, because of that it will produce volts. The stage of the s-capacitor, the rated input signal source, is connected to the aforementioned displacement amplifier to generate the deflection current in the coil. For the aforementioned diffraction amplifiers, the deflection amplifiers include a control circuit which forms a negative feedback loop and will respond to the aforementioned input signals for lead control. The currents of the first and the second output sectors mentioned, and Sections for independent operation of the said feedback loops and in response to the voltages of the aforementioned s-capacitors and to the said control circuits to stop the conduction of the sectors. The first output mentioned when the s-capacitor voltage is below the nominal size 1. 3. The deviation cycle consists of Coil for deflection The deflection coil is connected to the output terminal of the aforementioned displacement amplifier. The s-capacitor is connected to the aforementioned displacement winding and is charged during steady-state operation via the primary charge path, which includes the primary conduction path within the amp. Ur for the said turn to get the voltage of the s-capacitor. The control circuit continues to the distortion amplifier and responds to the input signal that determines the deflection for generating the deflection current in the deflection coil as mentioned. Mi is said to respond to the voltages of the aforementioned s-capacitors, suppressing the power amplifiers for deflection when the s-capacitor voltages. Is less than the size of the specified voltages, and The aforementioned s-capacitor charge path which runs through the said primary charge path of the charge and initiates the s-capacitor discharge during the initial period to perform Provides the aforementioned amplification amplifiers to be able to work. 4. Deviation circuit corresponding to claim 13, where the auxiliary charge path is shorted through the aforementioned displacement coil 1 5. The deflection circuit, according to Clause 14, in which the said s-capacitor is connected to the terminal of the deflection winding away from the output terminal at Said 1 6. Deflection Circuit According to Clause 15, where the above-mentioned main current conduction path is the main path of the transistor output sector within the diffusion amplifier at And where the aforementioned control circuit includes a direct current path for causing the base current to flow forward in the output sector of the aforementioned transistor from the aforementioned DC volt stage supply. The current will be stopped when the voltage of the said s-capacitance is less than the nominal voltage of the s-capacitance 1. 7. Circulation circuit, as claimed, Article 16, in which the aforementioned DC path includes the primary current path of the said s-capacitance voltage semiconductor component. It is then fed to the semiconductor element to block the primary current path when the s-capacitance of the said voltage is less than the nominal size of the voltage 1. 8. The deviation cycle consists of The deflection amplifiers will include the output image of the first and second transistor amplifiers. The differential and s-capacitance coils are connected in series to the output sectors of the aforementioned first and second transistor amplifier at the output terminals. Amplifier output For the s-capacitance amplification, the amplitude is thrown across the said capacitance during the operation of the amplifiers for the said displacement. already The source of the signal given for the deflection to be connected to the aforementioned deflection amplifier to generate the deflection in the aforementioned deflection coils; and The base current generator is connected to the output region of the aforementioned transistor amplifier to bring the base current to it. The aforementioned base current generator circuit is connected to the s-kapa. So The mentioned s-capacitance voltage stage is based on the aforementioned s-capacitance voltage source as a source of DC voltage to induce the conduction of the aforementioned base current 1. 9. The vertical deflection circuit of the video display device, with the vertical deflection circuit initiated that is prolonged until the shortest after the magnetic decompression, consists of: Switch On: Off The decoupling circuit responds to the on-off switch as described above to obtain a decompression reaction during the initial release of the magnetic field. The on-off circuit is switched on in the on position. The vertical deflection circuit includes a vertical deflection coil and a capacitor, which in the capacitor. It provides a vertical rate-setting voltage during steady-state operation, which controls the vertical deflection in the coil for the aforementioned deflection. DC power supply for the generator DC supply voltages that will generate the power in the circuit for the aforementioned DC power supply, the aforementioned DC power supply will react the on-off switch. As already mentioned, to operate the aforementioned DC Supply Volt after the aforementioned on-off switch has been switched to the on (on) position of the said DC supply volt into The appropriate level to produce the power in the circuit for the vertical deflection mentioned before the parent field relaxation period. The said iron will end. For the charging of the aforementioned capacitors from the DC power supply after the aforementioned on-off switch is switched to the on position at a sufficiently slow rate to The induced deflection time is prolonged after the aforementioned magnetic field relaxation period has ended.