DE2260261C3 - Electrical circuit arrangement for generating holding voltages of rectangular shape for a display panel - Google Patents

Description

The invention relates to an electrical circuit arrangement using for generating holding voltages of rectangular shape for a display panel of gas discharge cells with conductors arranged in rows and columns, which are dielectrically drawn from the gas space are arranged isolated, each with one provided for the rows and columns, consisting of switching transistors and control circuit that can be controlled by control signals for applying the holding voltage to the conductors via a selection matrix each for igniting and extinguishing selected gas discharge cells, in which Control circuit a transistor amplifier is provided.

Such a circuit arrangement for controlling display panels with gas discharge cells is off

known from U.S. Patent 34 99J67

The gas discharge cells are also here constantly charged by a whale tension to them to keep in the ready-to-ignite state while igniting and deleting individual selected lines done by impulses. Between the holding voltage source and the means for switching off the holding voltage to the display panel can be a or several amplifier stages can be arranged.

It has been shown that the withstand voltage suffers more or less severe distortion that of it depends on how many individual gas discharge cells are activated simultaneously or one after the other. Through this the capacitive resistance of the display board changes considerably Discharge changed the shape of the holding voltages. This will improve the performance of the scoreboard deteriorates and can in particular their storage function, namely the maintenance of the discharges are disturbed in the gas discharge cells.

The invention is therefore based on the object of designing the amplifier circuit in such a way that the rectangular shape the holding voltage lower distortion

having. .

This object is according to the invention with the circuit arrangement the type described above solved in that the transistor amplifier consists of two amplifier transistors controlled by the respective control circuit exists whose common connection point with the selection matrix of the display board is connected, and that a feedback circuit is provided for each amplifier transistor.

The advantage thus imparted is that the feedback voltage is proportional to the load current of the holding voltage and when it is variable Impedance of the display board, i.e. when igniting a different number of gas discharge cells, a better shape of the holding voltage is achieved The circuit arrangement designed according to the invention also has the advantage that it cannot short-circuit the power supply for a short time, so that lower Requirements placed on the power supply and heat losses can be reduced. Also the circuit arrangement works essentially without delay.

Feedback circuits for transistor amplifiers are known per se (DT-AS 19 34 797). The well-known However, the circuit is in view of the present task and with regard to the connection of the Control circuit via the amplifier stage to the selection matrix of the display board cannot be used.

An embodiment of the invention is explained in more detail below with reference to the drawing. It shows

F i g. 1 is a schematic representation of the display panel.

F i g. 2 a simplified block diagram of the circuit arrangement,

F i g. 3 is a circuit diagram showing the details of the circuit arrangement for generating Holding voltages.

The display panel 10 with gas discharge cells of FIG. 1 has that known from US Pat. No. 3,499,167 Construction and consists of two carrier plates 11 and 12 on which the conductors 13 and 14 in Rows and columns are arranged; the conductors are provided with dielectric insulating layers 15 and 16, so that no current reaches the gaseous medium from the conductors via the dielectric coating

Eßfcnn; ie the cross points of the matrix arrangement, which are formed ipilllirch * the crossed conductors, are arranged dielectrically insulated from f§§iijenii gas space. The corresponding plates are arranged at a distance from one another and connected to one another by a denser spacer 17 in order to form a thin gas discharge tank in which a neon-argon-SiSi) SCh ¹¹¹¹ S (preferably 99.9% neon and 0.1% argon) according to FR-PS 2019 723. The gas space can also be filled with other gas discharge carriers. however, owing to the improvement achieved with the aid of the above-mentioned gas mixture, the panels can be operated in the range from 30 to 50 kHz without being damaged by a drop in temperature; At the same time, they result in a good actual yield and strong storage reserves. The dielectric or insulating layers 15 and 16 can be coated with a lead oxide coating (not shown) to reduce the operating voltage. k The individual conductors 13 of the rows are preferred

wise through the selection matrix 20 and the individual conductors 14 of the columns, preferably through the selection matrix 21 controlled, these selection matrices are not essential to the invention and consist of multiplex or Non-multiplex diode resistor circuits are best can hen. For optional control of the conductors, instead of the multiplex operated selection matrix individual pulse circuits can be used. Input signals are applied to selection matrices 20 and 21 a signal source, not shown, which is a computer, a set of keys, a punched tape reader or another data source.

The two voltage sources 30 and 31 supply the conductors 13 and 14 of the panel 10 with holding voltages opposite phase or polarity.

One half of the holding voltage for the board is applied to the row conductor and the other half to the Column conductor applied, it should be noted that the voltage sources 30 and 31 the common terminal G », which does not necessarily have to be mass, so that in the arrangement shown the through the selection matrix 20 for the voltages generated in the rows is related to the voltage of the voltage source 30 are and in a similar way the voltages for the ignition and discharge, which are in the selection matrix for the columns are generated, are connected in series with the voltage source 31 and their instantaneous voltage serves as a reference voltage. In addition, there are logic at the two voltage sources 30 and 31 Control signals from the data source 32, which can be a multivibrator or another signal source, like a calculator, can be. For example, it may sometimes be desirable to have the ad delete, with one of the signals applied to one of the voltage sources 30 and 31 simply for a specific Time is turned off, which clears the gas information of the panel or it may also be desirable the nominal holding voltage by changing the nominal voltage of the data source 32 change.

In the block diagram of FIG. 2, the control circuit for applying the holding voltage consists essentially of the two saturation-free transistor amplifiers 41 and 42, whose common connection point 43 is via the connection point shown in FIG. 1 is led to the corresponding row or column conductor of the board. The capacitor Cp is connected to the prevention point 43 and serves as an equivalent circuit diagram for the capacitance of the display panel. It should be noted that this capacity represents the table capacity and does not necessarily have to be present.

The saturation free transistor amplifiers 41 and 42 have their own positive feedback circuit 44 and 45, their respective output signals together with the logic or control voltages of the Coupling circuits 48 and 49 the input circuits of the saturation-free transistor amplifier via the summing elements 46 and 47 are fed. In addition, the bypass diode 50 forms a return path for the Reverse currents when the voltage source 31 on the other hand changes polarity; then forms the corresponding Diode 50 of voltage source 30 provides a return path for the displacement current of the panel.

In Fig. Referring to Figure 3, there is shown in detail a control circuit for a ladder assembly, it being understood that the conductors in the assemblies may be subdivided or grouped with one control circuit being provided for each section or group of conductors of the panel. The control signals Si and 52 (Fig. 1) are from a logic voltage source (data source 32, Fig. 1) via the transformers 7 "1 and Tl , the ground connection Gl represents the ground or reference potential for the applied logic signals. Since the upper half of the circuit is essentially the same as the lower half, it will first be described: First, the signals formed in the secondary winding of the transformer 71 pass through the decoupling resistors 40 and 41 to the bases of the transistors 42 and 73. The transistor 42 is over the resistor 44 and the bypass capacitor 45 are connected to the base of the transistor 46, the connection to the high-voltage source Vcc being established via the resistor 47. The collector of the transistor 46 is connected to the voltage divider consisting of the resistors 48 and 49, the connection point 50 between the two resistors is connected to the diode 51. The cathode of the diode 51 is connected to the Bas is connected to the transistor 52, the output voltage of which is fed to the base of the transistor 53 via the small resistor 54. The collector of the transistor S2 is led via the cut-off resistor 56 to the connection point 43 of the circuit arrangement.

The transistor 53 works as an emitter follower and is connected so that it cannot turn on. the Resistor 57 with a very small ohmic value is connected into the collector circuit of transistor 53. the Resistor 57 is in a positive feedback circuit, which also includes control transistor 52, the resistor 58 and line 59 includes.

The transistor 73, which is led to the voltage source Vcc via the resistor 74, is used for phase reversal; its output is fed to the base of transistor 61 via the acceleration RC element 60. The collector of transistor 61 is connected to the base of transistor 52 via resistor 62. Under operating conditions the impulse applied to the primary development of the transformer 7 "1 is transferred to the secondary winding induced and reaches the bases of transistors 42 and 73 at the same time. If thus, for example a positive voltage is induced in the secondary winding of the transformer Pl, then this positive voltage applied to the bases of transistors 42 and 73 through the phase reversing transistor

73 reversed and reaches the base of transistor 61. The output signal of transistor 61 passes over the resistor 62 to the driver transistor 52 and controls this through. The driver transistor 52 triggers in turn a current flow in the emitter follower transistor 53 and in the feedback resistor 57 from. So the Current on its way to the consumer in this series circuit via the positive feedback resistor 57, and the voltage generated across this resistor is sent to the base-emitter circuit of the Transistor 52 for controlling the switching state of transistor 53. Therefore, this is feedback voltage directly proportional to the load current.

The diode 51 is used to switch off the feedback circuit when the control signal developed at the transformer Pi is no longer present. When the pulse generated in the secondary winding of the transformer Tl reaches the base of the transistor 42, this transistor transmits its output signal to the base of the transistor 46, whereby it is driven and the full bias voltage is applied to the anode of the diode 51 in order to prevent it Bias the clamping diode in the reverse direction. When the control signal from the base of the transistor 42 is no longer present, the transistor 46 blocks and ensures that the voltage present at the connection point 50 (with the exception of the voltage difference at the ends of the diode series circuit 70) is sufficiently large. in order to bias the diode 51 in the forward direction and thus also large enough to switch off the feedback circuit from the feedback resistor 57. The diode 50 is provided in order to form a return path for the reverse current when the polarity of the voltage source on the opposite side of the panel 11 is reversed. If this diode were not switched on, then the charge on the board or on the consumer could hold a transistor 53 via the resistor 56 in the activated state. The diode 72 is provided for the general case when a phase-shifted device is connected to the panel.

With the aid of this circuit arrangement, the feedback voltage is directly proportional to the load current since a higher current flows to the load and thus a higher positive feedback is introduced when more gas discharge cells are switched on on the panel. It should be noted that the lower half of the circuit is essentially identical to the upper half, except that the lower half of the circuit lacks the phase inversion transistor 73. As already explained above, the logic control signal S2 applied to the transistor 72 represents a blocking pulse, the control signal Si being within the opening pulse applied to the transformer Ti. This results in a security band on each side of the control signal Si, which ensures that the opening and blocking pulses are never turned on at the same time. Instead of the opening and blocking pulse of the transformer, four separate logic control signals can also be provided. By using the transistor 73, the second group of control signals can be avoided. It should be noted that the control signals applied to the transformers 71 and 72 can be variable in order to change the timing zt and thus also the width of the holding right corner voltages. What is essential is the use of the low resistance 57 in a positive or regenerative feedback circuit with the driver stage 52 and the amplifier transistor 53 for supplying the display panel with holding rectangular voltages.

For this purpose 2 sheets of drawings

Claims (5)

ψ -) \ - claims: r 1. Electrical circuit arrangement for generating holding voltages of rectangular shape for a display panel using gas discharge cells with conductors arranged in rows and columns, which are arranged dielectrically isolated from the gas space, each with one provided for the rows and columns, consisting of switching transistors and controllable by control signals / control circuit for applying ^ the holding line r: to the conductors via a selection matrix each for igniting and deleting selected gas discharge cells, where &^; In the control circuit a Traiisistorver- ■ is provided, thereby ^ eTc e η η-, ζ eich η et that the transistor amplifier ats two amplifier transistors (53, 53 ') controlled by the respective control circuit, whose common connection point (43) with the selection matrix (20, 21) of the display board is connected. and that a feedback circuit (44, 45; 52, 57, 58, 59) is provided for each amplifier transistor. 2. Circuit arrangement according to claim I. characterized in that the feedback scha! - device (44, 45; 52, 57, 58, 59) each one connected in series with the amplifier transistor (53, 53 ') has low resistance (57, 57 ') through which the load current of the holding voltage flows where the feedback voltage is proportional to the load current. 3. Circuit arrangement according to claim 2, characterized in that the low-resistance Resistance (57, 57 ') between the common connection point (43) and the base of the amplifier transistor (53, 53 ') is damaged in order to increase the voltage drop time of the amplifier transistor shorten. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that diodes (51, 51 ') for switching off the feedback circuit (44, 45; 52, 57, 58, 59) are provided when the control signal (Sl, S2) the control circuit (48, 49) for the transistor amplifier is switched off. 5. Circuit arrangement according to claim 4, characterized in that between the control circuit and the amplifier transistor (53, 53 ') a driver stage (52, 52') is provided and the Diode (51.5Γ) is connected upstream of the driver stage. 50