KR100297600B1 - On screen display device and method - Google Patents

Abstract

PURPOSE: An on screen display device and method are provided to compress video RAM data using special character code data to write the compressed data in a video RAM, offer a variety of character fonts, and maximize efficiency of the video RAM. CONSTITUTION: An on screen display device includes a video RAM(85) in which character code data and column code data are written through a data bus and an address bus, an address control logic circuit(75) for generating a row address and a column address for sequentially accessing the video RAM, and a character code pre-decoder(90) for decoding a signal output from the video RAM. The device further includes a character font ROM(95) for receiving the decoded data output from the pre-decoder, an EEPROM program control circuit(100) for controlling the character font ROM, and an output control logic circuit(105) for receiving characters output from the character font ROM to display the characters on a screen.

Description

On-screen display device and method

1 shows a functional block diagram of an on-screen display device according to the prior art.

2 is a diagram showing a configuration of a video RAM according to the prior art and an example of an on-screen display.

3 is a functional block diagram of an on-screen display device according to the present invention.

4 is a diagram showing a configuration of a video RAM and an on-screen display according to the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an on-screen display device, and more particularly, to an on-screen display device and an on-screen display method incorporating an EEPROM type font font ROM to be suitably used for a television or a high definition television (HDTV). will be.

In general, in an on-screen display device, character information is stored in a memory such as video RAM as character code data. When character code data stored in the video RAM is scanned on a cathode-ray tube (CRT) screen to display the information, the character code data is sequentially output from the memory in synchronization with the scanning operation of the CRT, and the character font ROM Is converted into dot data representing the character to be displayed. This dot data is then fed to the CRT.

On-screen display devices have built-in character font ROMs, which typically consist of mask ROMs. Since the mask ROM has a problem in that the mask has to be re-created as the ROM data is changed as already known, the user cannot change the character font data stored in the mask ROM.

Typically, it is known that an on-screen display device has a means for outputting a character corresponding to character code data from a character font ROM and then synthesizing it with character color data output from a video RAM.

1 is a functional block diagram of an on-screen display device according to the prior art. 2 is a view showing a configuration of a video RAM according to the prior art and an example of an on-screen display.

In FIG. 1, when character code data and color code data are written to video RAM 5 through the data bus and the address bus, the column addresses generated from the tote and column counter 10 and the row addresses generated from the line and row counter 20 are stored. The video RAM data, that is, the character code data and the character color data corresponding to the font address of the character font ROM 15 are output from the video RAM 5, and the characters corresponding to the data in the output character code are output from the character font ROM 15 and output. It is input to the control logic circuit 25.

The control signal output from the XOR means 35 and 40 is input to the output control logic circuit 25. The XOR means 35 and 40 are input with the output signal output from the horizontal synchronous signal H-SYNC, the vertical synchronous signal V-SYNC, and the polarity selector 30, respectively. In addition, line coefficient data output from the line and row counter 20 is also input to the output control logic circuit 20. The output control logic circuit 25 logically synthesizes the characters output from the character font ROM 15 and the character color data output from the video RAM 5. Thus, the character code data and the color code data are synthesized and displayed on the screen.

In the on-screen display device according to the related art shown in FIG. 1, the method of MAPPING video RAM 5 on a video screen in a one-to-one manner has a fixed character position corresponding to the video RAM address on the screen. The number of columns that can be displayed on the screen is fixed according to the size of the video RAM.

The video RAM for the on-screen display shown in FIG. 2 is 249 bytes (BYTE) video RAM for the on-screen display. The character code data corresponding to the video RAM address is a grid of 24 horizontal columns and 10 vertical rows on the CRT screen. You can see that it is mapped. That is, as shown in FIG. 2, since the number of characters displayed on the screen is fixed, in order to increase the number of characters displayed on the screen, the number of lines and columns of characters must be increased. However, in order to increase the number of lines of characters and the number of columns, the video RAM size must increase proportionally.

In this case, due to the increase in resolution due to the increase in the scanning lines such as high-definition television (HDTV), a larger size video RAM is required to display more characters using a wide screen for HDTV.

On the other hand, since the character font ROM 15 shown in FIG. 1 is composed of a mask ROM, there is a problem that a mask must be re-created every time a change of the ROM data occurs. Therefore, the user cannot easily change the character font data arbitrarily. In addition, since changing the character font ROM data takes a lot of time, it is difficult for a user to develop an application program using various character fonts.

As such, in order to provide various character fonts to the user, the size of the character font ROM should be increased.

Accordingly, an object of the present invention is to provide an on-screen display device capable of providing various character fonts.

Another object of the present invention is to provide an on-screen display device that can maximize the efficiency of video RAM.

It is still another object of the present invention to provide an on-screen display device capable of compressing video RAM data and writing it to video RAM using special character code data.

It is still another object of the present invention to provide an on-screen display device capable of enabling a multi-timing program by configuring a character font ROM as an EEPROM.

Another object of the present invention is to provide an on-screen display method that can compress video RAM data and write to video RAM using special character code data.

An object of the present invention as described above, in an on-screen display device, a video RAM in which character code data and column code data are written through a data bus and an address bus, and row addresses and addresses for sequentially accessing the video RAM. A control logic circuit for generating a character set; a character code predecoder for decoding an output signal output from the video RAM; an EEPROM type character font ROM for receiving data output from the character code predecoder; and the EEPROM type character. An EEPROM program control circuit for controlling a font ROM and an output control logic circuit for receiving a character output from the character font ROM and displaying a screen state are achieved.

Another object of the present invention is an on-screen display method, comprising the steps of writing character code data and color code data onto video RAM, and sequentially ordering the video RAM by row and column addresses generated from an address control logic circuit. Accessing, decoding the output signal output from the video RAM through a character code predecoder, receiving data output from the character code predecoder by an EEPROM type character font ROM, and the EEPROM program And a process of controlling the EEPROM type text font ROM by a control circuit and receiving the characters output from the text font ROM and displaying them on the screen.

Hereinafter, the present invention will be described in more detail with reference to FIGS. 3 and 4.

3 is a functional block diagram of an on-screen display device according to the present invention. In FIG. 3, character code data and color code data corresponding to one frame are written to the video RAM 85 via the data bus and the address bus. The storage areas in the video RAM 85 are sequentially accessed by the row address and column address output from the address control logic circuit 75.

The character code data signal output from the video RAM 85 is decoded by a character code predecoder 90. At this time, when the output signal output from the video RAM is normal character code data, the output signal of the character code predecoder 90 becomes the address of the character font ROM 95. On the other hand, when the output signal output from the video RAM 85 is special character code data, the character code predecoder 90 generates a control signal of a character code used as an address control logic circuit, thereby converting the video RAM 85 and the character font ROM 95. Control. At this time, the character font ROM is configured in the EEPROM type to enable multi-time read, write and erase. In addition, various font data can be written from the outside into the EEPROM inside the character font ROM, thereby providing various fonts. On the other hand, the EEPROM type character font ROM is controlled by the EEPROM program control circuit 100. The EEPROM program control circuit 100 receives a high voltage, an EEPROM program control signal, an EEPROM address, and character font data, respectively.

4 is a diagram showing the configuration of a video RAM and an on-screen display according to the present invention. In the example of conventional video RAM configuration and on-screen display, the video RAM in the on-screen display is mapped one-to-one with the screen, so that 24 horizontal columns are displayed regardless of whether one character is displayed on the screen or all characters are displayed. And video RAM corresponding to a grid of 10 vertical rows is equally required. In addition, since rows and columns are fixed according to the size of the video RAM, application limitations have been described when using a wide screen, which is a display for HDTV.

However, if it has a configuration of the video RAM according to the present invention as shown in Fig. 4, it is assumed that it has the same size as the video RAM according to the prior art, the clock frequency corresponding to the dot size of the displayed characters As long as the size of the screen allows, 240 characters corresponding to 10 x 24 can be displayed on one line.

As shown in the configuration of the video RAM and the on-screen display as shown in FIG. 4, one of the most important features of the present invention is a special character such as a space character code including a new line code and the number of repetitions. The code can be used to compress the video RAM data. Of course, there is little difference in displaying all characters in the display process, but in actual application, it is rare to display all characters and a space is inserted between most characters. By using the special character code according to the present invention, it is possible to remove the restrictions on the use of columns and rows, and to effectively use video RAM.

The on-screen display device according to the present invention as described above has the effect of maximizing the efficiency of video RAM by compressing the data of the video RAM using a special character code and writing it to the vivid RAM. In addition, by configuring the character font ROM as EEPROM, multi-timing programming is possible, and user can define and read and write the required character font arbitrarily. Font ROMs have the effect of enabling the development of applications.

Claims (6)

In the on-screen display device, A video RAM in which character code data and column code data are written through a data bus and an address bus; Address control logic for generating row addresses and addresses for sequentially accessing the video RAM; A character code predecoder for decoding and outputting a signal output from the video RAM; A character font ROM of type EEPROM that receives decoded data output from the character code predecoder; An EEPROM program control circuit for controlling the EEPROM type character font ROM; And an output control logic circuit for receiving a character output from the character font ROM and displaying a screen state. The on-screen display device according to claim 1, wherein when the output signal output from the video RAM is a normal character code, the output signal of the character code predecoder is the EEPROM type character font ROM address. 3. The method of claim 2, wherein when the output signal output from the video RAM is special character code data, the character code predecoder generates a control signal of a corresponding character code to the address control logic circuit so as to generate the video RAM and the video RAM. An on-screen display device characterized by controlling an EEPROM type character font ROM. In the on-screen display method, Writing character code data and color code data onto a video RAM; Sequentially accessing the video RAM by row and column addresses generated from an address control logic circuit; Decoding an output signal output from the video RAM through a character code predecoder; Receiving data output from the character code predecoder by an EEPROM type character font ROM; Controlling the EEPROM type character font ROM by the EEPROM program control circuit; And receiving a character output from the character font ROM and displaying the character on the screen. The on-screen display method according to claim 4, wherein when the output signal output from the video RAM is character code data, the output signal of the character code predecoder becomes the EEPROM type character font ROM address. 6. The method of claim 5, wherein when the output signal output from the video RAM is special character code data, the character code predecoder generates a control signal of a corresponding character code to the address control logic circuit to generate the video RAM and the video RAM. An on-screen display method characterized by controlling an EEPROM type character font ROM.