KR100496280B1 - Anode driving circuit of vacuum fluorescent display panel - Google Patents

Abstract

The anode driving circuit of the vacuum fluorescent display panel according to the present invention includes a decoder and an anode driving unit. The decoder operates in accordance with a control signal from the main controller to generate font selection data according to parallel data from the main controller. The anode driving unit stores display output data corresponding to the font selection data and operates in accordance with a control signal from the main controller to apply a display driving signal corresponding to the font selection data from the decoder to the anode terminal portion of the vacuum fluorescent display panel. do.

Description

Anode driving circuit of vacuum fluorescent display panel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an anode driving circuit of a vacuum fluorescent display panel, and more particularly, to a circuit for processing data input from a main controller and applying a display driving signal to each anode of a vacuum fluorescent display panel.

In a flat panel display panel, a vacuum fluorescent display panel has a performance similar to that of a cathode ray tube in that a fluorescent material emits light by a cathode ray. However, there is a difference that an electric radiation wire is used instead of the electron gun of the cathode ray tube. This electric wire forms a large area of electron emission region, the electron beam reaches the anode of the pixel selected by the anode driving voltage according to the image data, and emits fluorescent material.

In the vacuum fluorescent display panel which performs such an operation, the conventional anode drive circuit can process only serial data from the main controller. Referring to FIG. 1, a conventional anode driving circuit includes a series / parallel converter 11 and a cathode driver 12. The serial / parallel converter 11 operates in accordance with a control signal from the main controller to convert serial data from the main controller into parallel data. Here, the number of bits of parallel data input from the serial / parallel converter 11 to the anode driver 12 is equal to the number of terminals of the anode terminal 131 of the vacuum fluorescent display panel 13. The anode driver 12 amplifies the parallel data from the serial / parallel converter 11 while waiting in sequence, and applies a corresponding display drive signal to the anode terminal 131 of the vacuum fluorescent display panel 13.

The reason why the conventional anode drive circuit can only process serial data from the main controller as described above is that the anode drive circuit simply includes shift registers, latches, and amplifiers as the element as the anode drive unit 12. . Accordingly, the driving speed decreases, flickering occurs on the screen, and the control operation of the main controller needs to be large, and additional hardware is added to compensate for this.

SUMMARY OF THE INVENTION An object of the present invention is to provide a circuit capable of efficiently driving the anode of a vacuum fluorescent display panel by receiving parallel data from a main controller.

The anode driving circuit of the vacuum fluorescent display panel of the present invention for achieving the above object includes a decoder and a cathode driving unit. The decoder operates in accordance with a control signal from the main controller to generate font selection data according to parallel data from the main controller. The anode driving unit stores display output data corresponding to the font selection data, and operates according to a control signal from the main controller, thereby to display a display driving signal corresponding to the font selection data from the decoder. Applied to the positive terminal part.

Accordingly, the anode of the vacuum fluorescent display panel can be efficiently driven by receiving parallel data from the main controller.

Preferably, the anode driver includes a latch and a font ROM. The latch sequentially waits for font selection data from the decoder. The font ROM stores display output data corresponding to the font selection data. As the font selection data from the latch is applied as the address of the font ROM, the stored display output data is output, and the output display data is amplified to generate the display drive signal.

Hereinafter, preferred embodiments of the present invention will be described in detail.

Referring to FIG. 1, the anode driving circuit of the vacuum fluorescent display panel according to the present invention includes an 8 × 40 decoder 21 and an anode driver 22. The 8x40 decoder 21 operates in accordance with control signals from the main controller, i.e., a clock signal, a strobe signal and an erase signal, to generate 40-bit font selection data according to 8-bit parallel data from the main controller. Here, font is a general term for letters, numbers or symbols. The reason why the font selection data is 40 bits is because there are 40 fonts to be used in the vacuum fluorescent display panel 23. The vacuum fluorescent display panel 23 is manufactured in a dot matrix shape and driven.

The anode driver 22 stores display output data corresponding to font selection data, and operates in accordance with a control signal from a main controller, that is, a clock signal, a strobe signal, and an erase signal. The anode driver 22 also applies a display drive signal corresponding to the font selection data from the 8x40 decoder to the anode terminal portion 231 of the vacuum fluorescent display panel 23. For this operation, the anode driver 22 includes a 40 bit latch 221 and a font ROM 222. The 40 bit latch 221 sequentially waits for font selection data from the 8 x 40 decoder 21. The font ROM 222 stores display output data corresponding to font selection data. Here, the display output data stored in the font ROM 222 is defined to have a display area of 5 pixels horizontally and 7 pixels vertically per font, or a display area of 5 pixels horizontally and 12 pixels vertically per font. As the font selection data from the 40-bit latch 221 is applied as the address of the font ROM 222, the stored display output data is output, and the output display data is amplified to generate a display drive signal.

As described above, according to the anode driving circuit of the vacuum fluorescent display panel according to the present invention, the anode of the vacuum fluorescent display panel can be efficiently driven by receiving parallel data from the main controller, thereby increasing the driving speed. No flicker on the screen, less control of the main controller, and no additional hardware to improve drive speed.

The present invention is not limited to the above embodiments, and modifications and improvements are possible at the level of those skilled in the art.

1 is a block diagram illustrating an anode driving circuit of a conventional vacuum fluorescent display panel.

2 is a block diagram illustrating an anode driving circuit of a vacuum fluorescent display panel according to the present invention.

<Description of the symbols for the main parts of the drawings>

21 decoder, 22 anode drive,

221 ... latch, 222 ... font rom.

Claims (2)

A decoder operable in accordance with a control signal from a main controller to generate font selection data according to parallel data from the main controller; And Display output data corresponding to the font selection data is stored and operated according to a control signal from the main controller to apply a display drive signal corresponding to the font selection data from the decoder to the anode terminal portion of the vacuum fluorescent display panel. An anode drive circuit of a vacuum fluorescent display panel including an anode drive unit. The method of claim 1, wherein the anode drive unit, A latch that sequentially waits for font selection data from the decoder; And A font ROM including display output data corresponding to the font selection data, and outputting the stored display output data by applying font selection data from the latch as an address of the font ROM, and amplifying the output display data. And the display driving signal is generated to generate the display driving signal.