SU1029221A1 - Control device for gaseous-discharge display panel - Google Patents

Abstract

A DEVICE FOR CONTROLLING A GAS DISTRIBUTING INDICATOR PANEL contains two groups of bit transistors, the bases of which are connected to the clock bus, and the emitters on the bus of zero potential, and the charging key, the base of which is connected to one of the clock bus, the collector is connected to the positive bus, and Emitter - with charge diode cathodes, the anodes of which are connected to the corresponding coordinate tires of the gas discharge display panel, characterized in that, in order to make the device more efficient and to reduce power consumption, it contains a group of discharge diodes, the anodes of which are connected to the corresponding coordinate buses of the gas discharge indicator panel, and the cathode to the collectors of the corresponding discharge transistors of the first and second groups, $ (L s

Description

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1C The invention relates to automation and computational and can be used in devices for displaying information and content of gas discharge display panels of alternating current. A device for controlling a gas-discharge indicator bulb (HIP) is known, which contains two digital signals for horizontal electrodes, two groups of electronic switches,. source control wiring, decoupling and discharge diodes, summing resistors, GUIs and corresponding tl3 connections. A disadvantage of the known device is the high power consumption due to the flow of currents through the trap and close to the other elements, the KOTC IMJDC coherence is proportional to the number of HIP electrodes. Closest to the invention in its technical essence and achievable, the effect is a device for controlling the ISU, containing two key elements, additional. key element, sources of control and supportive voltages of a block of logic units, summation elements, a diode diode, two groups of developed HIP diodes and corresponding (the connection of the device’s disadvantages is the presence of an additional key element ensuring a sum of capacitors after the termination of a control pulse, a significant amount of power is emitted on this key element, and therefore a heat sink is needed. The use of capacitors instead of resistors does not solve the problem with because the capacitance of the summed cells and the operating frequency of the GUI control cannot be arbitrarily reduced. The control frequency in the limit coincides with the frequency of the support voltage, which for modern GUIs is 30-100 kHz, and the capacitance should be 2 times to replace the capacitance of the GUI electrodes, which is 5-8 pF. Under these conditions (with 200 pF, F b, kHz) the capacitance resistance of the summing element is about 15 kOn, which is only 2-3 times different from the nominal The wound of the used summation resistors. Consequently, a significant reduction in power is not. it turns out. The presence of a non-polar source of control voltage (50-100 volts) (im6 of total complication and increase in the Dimensional dimensions of the device also leads to unproductive power losses, such as the efficiency of modern power sources is 50-70% It forms three-level pulses, and the use of such a method to control the ISU requires an additional source of constant voltage (to intermediate the intermediate level} and the cost of a certain power. The purpose of the invention is to reduce power consumption. The goal is achieved by the fact that the device for controlling the gas-discharge indicator panel contains two groups of discharge transistors, the bases of which are connected to the synchronization buses, and the emitters to the zero potential bus, and the charging key, the base of which is connected to one of the synchronization signals. The collector is with a positive power bus, and the emitters are cathodes of charging diodes, the anodes of which are connected to the corresponding coordinate buses of the discharge and (shikatornoy panels) iodides, the anodes of which are connected to the corresponding co-ordinals of the gas discharge display panel, and the cathodes to the collectors of the corresponding discharge transistors of the first and second groups. ya fig. 1 is a schematic diagram of the device; in fig. 2 time diagram. The device contains the first group of discharge transistors 1, the second group of discharge transistors 2, charge key 3, charge diodes 4, coordinate discharge lines of the gas discharge display panel 5, zero potential 0, positive power bus 7, HIM) sync 8, group discharge diodes 9, the device operates as follows. The input is charged by the ego key 3 (Fig. 1) from the control unit via the synchronization buses and the charging synchro “switches” (and istuleles (t 1–2 μs) with a frequency of LO kHz are received and unlocked at B {f This time to produce a charge of all the electrode electrode capacitances to the magnitude of the output capacitance of the power supply. The potential of the charge is: the interelectrode capacitance capacitance remains until the onset of synchronous pulses on the Ipynny transistors 1. Work according to the principle of charge pulses q C GUI these transistors form an imp Support voltage (phi, 2u, S) in the support mode. In the control mode (write and erase J, the first and second groups of discharge transistors l and 2 together with the discharge diodes 9 form a matrix high-voltage decoder, by means of which the selected electrodes Impulses are generated by the ISU, and the ignition or suppression of selected cells is ignited. The control (recording or deletion) is achieved by expanding the impulses of the voltage applied to them by later unlocking the selected sources from 1 and 2 in comparison with all others. Ears and Election Choices In the device according to the coordinates (apr4r X), F0rin; there are two pulses of supporting voltage within the limit of one cycle (4mg. 2). between the first and second impulses supporting 11p | co-ordinate X, input of a pause sufficient for the formation of impulses of the maintenance voltage and impulses of starting the coordinate of the U. Process. More when recording and erasing information. In the recording mode, the first pulses maintain & a voltage across the selected electrodes, the X coordinates expand to the point of cutting off the recording pulses generated along the Y coordinate in the erase mode, the second pulses of the supporting voltage are expanded to the time of cutting the erase pulses generated along the Y Coordinate. And the voltage pulses of the supporting voltage are formed by the charge method of the inter-element capacitances of the ISU cells. and the instant t of the inter-element capacitance cells of the panel C is charged to the level of the output voltage of the power source — the front of the voltage of the supporting voltage on all buses of the X coordinate is formed. The discharge moment and, accordingly, the duration of the pulses maintained by the voltage X, depends on the mode work of the ISU. In the support (display) mode, all the inter-element capacitance capacitors, and without discharge, are discharged at time t, the formation of the cut-off impulse of the supporting voltage occurs. The duration of the pulses of the supporting voltage is then equal to the time interval tj t - t2. In the recording mode, the inter-element capacitances related to unselected buses AHW are discharged to a zero level at time t, 2, and voltage pulses of duration tj are formed on the high-speed tires. The cells related to the 1FAM bus remain under voltage EF during the time interval t | - and are discharged to the zero level only in the time period t This ensures that the X coordinate in the wide impulse control interval with the amplitude equal to Uy , (110 in). Simultaneously with the formation of them; pulse along the X coordinate, the control pulse is applied to the electrodes of the Y coordinate. The amplitude of this pulse is chosen such that the potential difference between the selected electrodes exceeds the ignition level of the HIP cells (on the order of 150 V). The resulting voltage between the electrodes of the selected cell is shown in FIG. 2e, and not selected in FIG. 2nd. After the occurrence of a gas sample in the selected cell on the dielectric layers of the ISU, a wall charge is created, the change of which is shown by the dotted line in Fig. 2. After a single breakdown of the gas gap and the creation of a wall charge, the selected cell continues to switch on its own, which is explained by the principle of operation of the AC type. In the recording mode, in the process of forming the resultant recording impulse, the first impulse of the supporting voltage participates, expanding the X coordinate on the selected electrode to the cutout of the recording impulse formed by the Y coordinate. expandable on the selected electrode of the X coordinate until the moment of erasing the erase pulse generated by the Y coordinate. The difference in sweat is applied to the selected ISU cell impulses, which is shown in the timing diagram of FIG. 2 (erase mode) in the form of two opposite-polarity pulses. An impulse having a rather short duration (t = 1 μs) disrupts the process of restarting the cell, as shown in the diagram of FIG. 2, transition of the wall voltage to the zero-zero level (the wall-wall voltage is shown by a dotted line). I, ... Thus, the device performs the same write-or-quench function, any GUI cell, but there are no special circuits along the X coordinate for generating control pulses, and the writing and erasing process is achieved by changing the pulse width of the supporting Cell. wives This difference made it possible to exclude the source of control voltage from the device and simplify the generator of the supporting voltage, leaving there only one charging key 3 to one constant voltage source. If the base object is performed on the basis of a GUI with 1 8x128 electrodes, then it will consist of two sources of constant voltage and 50 V

Claims (1)

DEVICE FOR MANAGING A DISCHARGE INDICATOR PANEL, containing two groups of discharge transistors, the bases of which are connected to the synchronization buses, and the emitters to the zero potential bus, and the charging key, the base of which is connected to one of the synchronization buses, the collector to the positive power bus, and the emitter to with cathodes of charging diodes, the anodes of which are connected to the corresponding coordinate buses of the gas discharge display panel, characterized in that, in order to simplify the device and reduce power consumption, it contains m bit group of diodes, the anode of which are connected to the corresponding coordinate buses discharge display panel, and the cathode - to the headers corresponding discharge transistors of the first and second groups. >