SU830370A1 - Information display device - Google Patents

Description

(54) DEVICE FOR DISPLAYING INFORMATION

The invention relates to radio electronics and can be used as an output device for various radio electronic systems, for example, radar stations operating in combination with a digital computer. A device for displaying information is known, which contains a matrix display panel, two registers, two decoders and a synchronizer 1. A disadvantage of the known device is a large amount of equipment due to the large number of transformers that must have high-voltage (up to 250 V) isolation between windings and must transmit large amplitude pulses. At the same time, the impedance of the output circuits for maintaining the discharge voltage is large, which causes distortion of the form of this voltage and reduces the range of the panel memory. In addition, transformers are not amenable to microminiaturization and require damping resistance to attenuate the parasitic oscillations that occur after the end of the current pulse, which increases the cost of the circuit and leads to cumbersome control circuits. The closest to the technical solution of the invention is a device for displaying information containing a matrix display panel, two registers, the outputs of which are connected to the information inputs of the corresponding decimators, the control inputs of which are connected to the corresponding outputs of the synchronizer, switches and voltage dividers 2. The disadvantage of this device is its complexity, due to the need to use a large number of keys (according to the number of panel electrodes). Since the keys are not galvanically connected to the housing for isolating the control circuits and the voltage generator circuit, special isolation elements (for example, transformers) are required. A generator of alternating (sinusoidal or impulse) voltage is required to form the maintenance voltage, which maintains the luminescence of the cells. A relatively high-voltage source is needed to power the generator.

The purpose of the invention is to simplify the device.

The goal is achieved by the fact that the control inputs of the first and second switches are connected to the outputs of the respective decoders, and the setup inputs are connected to the power bus, the outputs of the first switches are connected to the first inputs, and the outputs of the second switches are connected to the second inputs of the corresponding voltage dividers, third and the fourth inputs of which are connected to the outputs of the third switch, and the outputs to the corresponding electrodes of the matrix display panel, the control input of the third switch is connected to the corresponding one synchronizer, and the installation input is to the potential-free bus, and also because the voltage divider contains two series-connected capacitors and two series-connected diodes, the first capacitor plates connected to the first anode and the cathode of the second diode The outputs of the second capacitor plates are the first and second inputs of the voltage divider, and the cathode leads of the first diode and the anode of the second diode are the third and fourth inputs of the divider, respectively. FIG. 1 shows a diagram of the device; in fig. 2 - timing diagrams for the operation of the device. The device contains a matrix display panel 1, registers 2, synchronizer 3, decoders 4, first switches 5, second switches 6, third switch 7, voltage divider 8, first diodes 9, second diodes 10, first capacitors 11, second capacitors 12. Operation The device is illustrated by a timing diagram (Fig. 2), in which the following symbols are adopted: 13 is a pulse diagram of t, and tg, of synchronizer 3, controlling the position of the second switch (along the Y coordinate); 14 is a voltage chart at the output of the decoder 4 (along the Y coordinate); 15 is a voltage chart at the output of the first switch 5 (which selects a group of electrodes according to the Y coordinate); 16 is a voltage chart at the output of the second switch 6 (selecting electrodes in the group along the y coordinate); 17; - voltage diagram on horizontal electrodes in a matrix display panel; 18 is a diagram of t and tg pulses of synchronizer 3 controlling the position of the first and second switches (along the X coordinate); 19 is a voltage chart at the output of the decoder 4 (along the X coordinate); 20 is a voltage chart at the output of the first switch 5 (selecting a group of electrodes on the X coordinate); 21 is a voltage chart at the output of the second switch 6 (selecting electrodes in a group along the X coordinate); 22 is a voltage chart of the vertical electrodes of a matrix display panel; 23 is a graph of voltages on selected cells; 24 is a voltage chart on unselected cells.

When the device operates in each period T, pulses are generated at the output of switches 5 and 6 (along the Y coordinate) (diagrams 15 and 16) at intervals tt-tj, ts-te. The shaping of these pulses is achieved by setting switches 5 and 6 to these intervals, wherein the positive pole of the power source + Е is connected to the output. At the remaining intervals, the output of the switches is connected to the point of zero potential (to the housing). The control signals come from the synchronizer clock decoder 3. The synchronizer consists of a master oscillator, the signal of which is fed to a three-bit clock counter. The outputs of the clock counter are connected to the inputs of the clock decoder, at the output of which 8 control pulses are formed, conventionally indicated by intervals (Fig. 2). From the output of the first bit of the clock counter, the control pulses arrive at the control input of the third switch 7, according to which the switch keys 7 are closed at intervals tj-tj, 5, TB-t, tg-i (and open at intervals tj-t , ts-te, tr-ta (Fig. 2). If the capacitance of capacitors And and 12 is significantly greater than the capacitance of the electrode, then at intervals in each period, pulses are formed on the horizontal electrodes of the matrix display panel (diagram 17), the amplitude of which is E because at these intervals the switch outputs are connected to the source to the power supply + E, and the third switch keys are open. In the interval, the switches 5 and 6 (on the Y coordinate) are connected to the source -fE (diagram 18), and the keys of the third switch 7 are closed, as a result of which the capacitors 1Г and 12 are charged E. At intervals ts-tj, the outputs of switches 5 and b (by coordinate) are connected to the case, and the keys of the third switch 7 are open. Consequently, charged capacitors 11 and 12 are connected to the case by a positive pole and negative ones to the horizontal electrodes and electric ktrodah generated pulse of negative polarity. In the te-C interval, the horizontal electrodes are connected to the housing via the keys of the third switch, and the capacitors 11 and 12 are discharged to zero potential (Figure 27). These processes are repeated in each period T. Thus, alternating pulse voltages are generated on horizontal electrodes with an amplitude of pulses equal to E. The circuit in coordinate X occurs similarly and differs only in the moment of formation of pulses and coordinate X), which selects the electrodes in the group, in the absence of a sampling signal, are always connected to the body.

As a consequence, the alternating voltage has an amplitude of pulses of E / 2, since capacitors 11 and 12, having the same capacitance, form a voltage divider for pulse signals. The synchronizer ensures the formation of pulses at the outputs of the first capacitor (along the X coordinate) at intervals ts- t, tg-t., (Diagram 20), as a result of which the alternating voltage on the vertical electrodes (diagram 22) is out of phase with the voltage on the horizontal electrodes (Diagram 17). The cell of the panel, in the absence of sampling signals, is under a voltage equal to the algebraic difference of the pulses on the horizontal and vertical electrodes. Consequently, the amplitude of the pulses is E + 0.5 E 1.5 E. If such an amplitude is sufficient to maintain the discharge, the panel cells that are switched to the light state are maintained in this state indefinitely.

To switch the selected cells to the light state in one of the periods T, pulses from one of the keys of the first and second switches are formed on the interval (along the Y coordinate) (diagrams 15 and 16). As a result, a pulse is formed on one of the horizontal electrodes connected through a capacitor 12 with the selected key of the second switch and through the capacitor 11c with the selected key of the first switch (figure 17, interval), and on the other electrodes the pulse amplitude is. In the interval tg-13, pulses are generated at the outputs of one of the keys of the first and second switches, which control the selection of groups along the X coordinate and the sampling of electrodes in the group along the X coordinate (diagrams 20 and 21). Since in this interval the keys of the third switch 7 are closed, the vertical electrodes and capacitor plates 11 and 12 connected to them connected to the outputs of the selected switch keys are charged before voltage E. On the interval tjr-t the keys of the third switch are open, and the keys of the first and second switches (along the X coordinate) are connected to the housing. Therefore, a pulse is formed on the ti-t interval on the electrode connected to the two charged capacitors 11 and 12, the pulse amplitude is equal to E, and the pulse amplitude on the other electrodes is equal to Е / 2 due to the dividing voltage of the half-selected pair of capacitors 11 and L2. Thus, the selected cells, i.e. located at the intersection of the selected electrodes in the selected group are in the interval Uj-Ui, under the voltage 2E, and the unselected cells under the voltage 3 / 2E, which does not exceed the amplitude of the supporting voltage (diagram 34 and 35). If the voltage E of the power source is 0, such that 3 / 2E U | 2E, where 0 is the ignition voltage of the cells, then the selected cells will go into the light state, and the unselected ones will remain in the light state. The specified condition is non-rigid and is almost always feasible.

To control the state of the cells and maintain them in a light condition, the proposed device requires N + M switches for each coordinate for a panel having M-N electrodes for each coordinate. Moreover, the same elements are used both for the formation of pulses of a supporting voltage and for the formation of control pulses. In addition, in the proposed device, a lower voltage power source is required (the voltage of the power source is 1/3 less than in known devices). Reducing the number of active elements simplifies the circuit and significantly increases its reliability. For example, for a panel with a number of electrodes 256 for each coordinate in a known device, 256 keys with isolation elements for each coordinate and a generator of supporting voltage are required. In the proposed device, to perform the same functions, 16-f-16 32 switches galvanically associated with the housing are required, and the switches in the proposed device can be controlled directly by low-voltage logic elements.

Claims (2)

1. A device for displaying information comprising a matrix display panel, two registers, the outputs of which are connected to the information inputs of the corresponding descramblers, the control inputs of which are connected to the corresponding outputs of the synchronizer, switches and voltage dividers, in order to simplify the device, the control inputs of the first and second switches are connected to the outputs of the respective descramblers, and the installation inputs are connected to the power bus; the outputs of the first switches are connected to the first inputs s, and the outputs of the second switches - with the second inputs of the respective voltage dividers, the third and fourth inputs 7 which are connected to the outputs of the third switch and the outputs to the corresponding electrodes of the matrix indicator panel, the control input of the third switch is connected to the corresponding output of the synchronizer, and the installation input is connected to the zero potential bus. 2. A device according to claim 1, characterized in that the voltage divider comprises two series-connected capacitors and two series-connected diodes, with the first capacitor plates under I eight They are connected to the anode of the first and the cathode of the second diode and are the output of the voltage divider, the terminals of the second capacitor plates are the first and second inputs of the voltage divider, and the leads of the cathode of the first diode and the anode of the second diode are the third and fourth divider inputs. Sources of information taken into account in the examination 1. US patent number 3609746, cl. 348-324 publish 197.1.yyyy 2 Copyright certificate H-L-H № 404076, cl. G 06 F 3/14, 1976 (prototype). TJ InG / perGoTGTGGTGG GGTTGG closed state Mwtiea of the third KOHHijmamopa. (Rig.2