KR940007024Y1 - Drive circuit of fluorescent display by microprocessor - Google Patents

Abstract

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Description

Fluorescent Display Tube Driving Circuit Using Microprocessor

1 is an exemplary circuit diagram of a fluorescent display tube driving circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

10 microprocessor 20 ROM

30: address bus 40: data bus

50: RAM 60: I / O Port

70: integrated device for driving the anode electrode 80: integrated device for driving the grid electrode

90: fluorescent tube 100: clock generator

110: 3bit binary counter 120: 20 binary counter

130: trance

The present invention relates to a fluorescent display tube driving circuit, and more particularly to a fluorescent display tube driving circuit that can vary the display function of the fluorescent display tube using a microprocessor.

Recently, the development of a flat panel display is progressing, and a matrix type flat panel display is mainly used in the segment method. A fluorescent display tube, which is a type of flat panel display, has also been developed with a matrix type, and the matrix type has a more complicated driving circuit than the segment type. In order to drive a conventional matrix fluorescent display tube, a driving integrated circuit and a control circuit for driving the anode and grid electrodes of the fluorescent display tube are required. Data to be displayed is supplied to the anode electrode, and a scan signal is supplied to the grid electrode.

Since the control circuit is usually made of hardware to control a specific display function, it was not possible to perform various display functions. In addition, in order to perform various display functions with the hardware configuration, the circuit configuration becomes very complicated and it has to be limited. Therefore, in order to have wide use and versatility of fluorescent display tubes, the emergence of fluorescent display tube driving circuits capable of controlling various display functions has been required.

An object of the present invention is to provide a driving circuit of a fluorescent display tube that can perform a variety of display functions by using a microprocessor to solve the problems of the prior art as described above.

In order to achieve the above object, the present invention provides a driving circuit of a fluorescent display tube having an anode electrode driving integrated element for driving an anode electrode and a grid electrode of a fluorescent display tube and an integrated element for driving a grid electrode, wherein the fluorescent A ROM for storing a display control program of the display tube; A RAM for storing data to be displayed on the fluorescent display tube according to a program stored in the ROM, an input / output port for receiving data from the outside and transferring display data stored in the RAM to the anode electrode driving integrated device; The ROM, RAM, and I / O ports are connected to a data bus, and the ROM and RAM are connected to an address bus to control the ROM, RAM, and I / O ports according to a program stored in the ROM, and to process display data. It is characterized by having a microprocessor.

Referring to the present invention in more detail through the accompanying drawings as follows.

1 is an exemplary circuit diagram of a fluorescent display tube driving circuit according to the present invention. In FIG. 1, the microprocessor 10 controls the system by a program (software) stored in the ROM 20. In the microprocessor 10, the address of the ROM 20 is addressed through the address bus 30, the instruction data in the designated address is fetched and decoded through the data bus 40, and the memory request control signal is read according to the decoded instruction. I / O request control signal , Lead control signal And light control signal And so on. The ROM 20 stores a command program for controlling the display of the fluorescent display tube 90. The ROM 20 is a memory request control signal of the microprocessor 10 And lead signals Through its AND gate G1 and its output enable terminal. The instruction data in the address designated by the address data loaded on the address bus is supplied to the microprocessor 10 via the data bus 40. RAM 50 is a memory request control signal of the microprocessor 10 And light signal Output enable terminal of 2 through AND gate (G2) 2 and the chip select terminal of 2 via the NOT gate G5. Enter And the output enable terminal. When the input state is " L ", the data stored in the address addressed by the address bus 30 is output to the data bus 40, and the chip select terminal. When the input state is " L ", data on the data bus 40 is input and stored in the addressed address. The input / output port 60 receives data from the outside and temporarily stores the data for supplying display data on the data bus 40 to the anode electrode driving integrated device 70. The input / output port 60 is an input / output request control signal of the microprocessor 10. And light control signal Is the light input terminal of 2 through OR gate (G4) Input to external data supplied to 2 port A or B port and input / output request control signal. And lead control signal Is the lead input terminal of 2 through OR gate (G3) The display data is supplied to the anode electrode driving integrated device 70 connected to the C port of the input device 2.

The anode electrode driving integrated device 70 inputs display data from the input / output port 60 to generate respective driving signals of the anode electrodes of the fluorescent display tube 90, for example, 35 anode electrodes. On the other hand, the fluorescent display tube 90 is connected to the grid electrode driving integrated device 80 so as to receive a sequential scanning signal to two grid electrodes, for example, 20 grid electrodes.

The microprocessor 10, the anode electrode driving integrated device 70, and the grid electrode driving integrated device 80 receive a clock from the clock generator 100 to synchronize operation timing. The anode electrode driving integrated device 70 counts the clock with a 3-bit binary counter 110 and receives the count value in parallel. The grid electrode driving integrated device 80 receives the clock in series through the hexadecimal counter 120.

The anode and grid electrode driving integrated devices 70 and 80 are supplied with -5V as the VDD voltage and -40V as the VN voltage, respectively. An alternating current 110V is supplied to the filament electrode of the fluorescent display tube 90 through the transformer 130.

The operation and effects of the present invention configured as described above are as follows.

In the circuit of FIG. 1, a program is stored in the ROM 20 to display English letters, numbers, symbols, etc. on the fluorescent display tube 90 according to data applied to A and B lots of the input / output device 60. If it is assumed that the desired data is supplied to the A and B ports, specific display data is applied to the anode driving integrated device 70 under the control of the microprocessor 10 by the program in the ROM, and the grid driving integrated device 80 is provided. May be displayed on the fluorescent display tube 90 of size 35 × 20 or turned off by the sequential scanning signal.

As described above, the present invention can freely perform various display functions by S / W by driving a fluorescent display tube using a microprocessor, and only change S / W without changing H / W configuration when changing display function. Since it has universality, the use range of the fluorescent display tube can be greatly expanded.

Claims (1)

A drive circuit for a fluorescent display tube comprising an anode electrode driving integrated element 70 for driving an anode electrode and a grid electrode of a fluorescent display tube 90 and an integrated element 80 for driving a grid electrode, wherein the fluorescent A ROM 20 for storing a display control program of the display tube 90; A RAM 50 for storing data to be displayed on the fluorescent display tube 90 according to a program stored in the ROM 20; An input / output port 60 for receiving data from the outside and transferring the display data stored in the RAM 50 to the anode electrode driving integrated device 70; The ROM 20, the RAM 50, and the input / output port 60 are connected to the data bus 40, and the ROM 20 and the RAM 50 are connected to the address bus 30. 20. A fluorescent display using a microprocessor, comprising a microprocessor 10 for arithmetic processing of display data by controlling the ROM 20, the RAM 50 and the input / output port 60 according to a program stored in Tube drive circuit.