KR920010381B1 - Drive circuit of on screen display bar - Google Patents

Abstract

The circuit detects and displays temperature on a screen of a television through a bar graph. The circuit includes a microcomputer (10) for generating control signal of a system and for generating temperature data according to sensed temperature, a temperature sensor (20) controlled by the microcomputer to detect temperature, a linear buffer (30) for converting analog temperature signal to digital signal and for transmitting digital temperature signal to the microcomputer, an OSD signal generator (40) for generating OSD signal according to temperature data transmitted from the microcomputer, and a CRT matrix unit (60) for overlapping temperature OSD data over video signal.

Description

Temperature Sensing OSD Bar Drive Circuit

1 is a circuit diagram according to the present invention.

2 is a temperature sensing display output state according to FIG.

* Explanation of symbols for the main parts of the drawings

10: microcomputer 20: heat sensor

30: linear buffer 40: OSD generator

50: video chroma processing unit 60: CRT matrix

70: CRT

The present invention relates to an OSD bar drive circuit that can sense the temperature and display the temperature as an OSD (On Screen Display) bar on a cathode ray tube (CRT).

In general, OSD refers to superimposing some information on the video screen of the main body. In the past, there was a function to superimpose a time display indicating the time on the CRT or a display indicating the channel information on the original image. In addition, there was a noise detection function that detects noise in the channel.

However, when the user watched the video screen, there was no function of displaying the ambient temperature or the internal temperature of the device with the OSD.

Accordingly, an object of the present invention is to provide an OSD bar drive circuit that can sense the temperature as a thermal sensor and display the OSD on the screen of the CRT.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a circuit diagram of a temperature sensing OSD bar drive according to the present invention. The microcomputer 10 generates a temperature value data in response to an applied digital signal by outputting a control signal which is processed by a predetermined program to control overall operations of the system. ), A thermal sensor 20 for sensing an electric temperature by a control signal of the microcomputer 10, and generating an electrical signal, and inputting an output of the thermal sensor 20 and linearly according to the input signal. A linear buffer 30 for outputting a digital signal to the microcomputer 10, a OSD generator 40 for inputting temperature data of the microcomputer 10 to generate a corresponding OSD signal; A video chroma processing unit 50 for inputting a complex image signal to the input terminal 24 for chroma processing, and an output of the OSD generation unit 40 and the output of the video chroma processing unit 50 are input. And it consists of a CRT (70) to the input of a signal extracted in the CRT matrix section 60 and the CRT matrix (60) for extracting the signals displayed on the screen.

2 is a temperature sensing display output state according to the present invention (2a) shows the current temperature displayed OSD on the CRT screen.

Hereinafter, the present invention will be described in detail with reference to FIGS. 1 to 2 based on the above-described configuration. In FIG. 1, the heat sensor 20 senses a temperature inside or outside and outputs an electrical signal accordingly. It is composed of a thermistor (Thermistor), the thermistor is commonly referred to as "Thermally Sensitive Resiste" and means a temperature-sensitive resistor, a sintered body of metal oxides such as manganese, nickel, cobalt, iron, copper, etc. A thermistor whose resistance decreases with increasing temperature of NTC (Negatibe Temperature Coefficient Thermistor) type of linear (Iiner) was used.

In addition, the heat sensor 20 is attached to the inside or outside of the device so that the user can know the external ambient temperature or the temperature inside the device.

First, when the user wants to display the current temperature state on the original screen of the CRT 70, the user selects a display signal through the microcomputer 10.

The microcomputer 10 then sends a control signal to the thermal sensor 20 and the linear buffer 30. Here, the control signal CNTR will be described in more detail. First, the signal applied to the thermal sensor 20 is a high or high temperature for operating the thermal sensor 20 which is a thermistor. It is a looping switching signal. In other words, when the thermistor is operated when the user does not want it, power consumption of the power source is consumed, so that the microcomputer 10 switches only when necessary. The signal applied to the linear buffer 30 is also an active signal having a high or low shape for the linear buffer 30 to be active. The microcomputer 10 scans whether a user digits a predetermined designation key for indicating a current temperature state, and outputs the control signal to the thermal sensor 20 and the linear buffer 30 when the designation key is digitized. Is applied separately).

Therefore, the heat sensor 20 performs an operation to detect an external or internal temperature and converts it into an electrical signal and outputs it.

The linear buffer 30 inputs the output of the thermal sensor 20 to amplify linearly, converts the digital signal into a digital signal, and outputs the digital signal to the microcomputer 10. That is, the digital signal is changed according to the output of the thermal sensor 20. For example, assuming that the voltage of the sensor 20 at 20 degrees Celsius is 2 volts, the linear buffer 30 The A / D converted value after amplified by the predetermined amplification factor is the digital signal. Therefore, it can be seen that the digital signal changes correspondingly every time the temperature changes.

Therefore, the microcomputer 10 inputs the output of the linear buffer 30 to the input terminal tp, and then programs the microcomputer 10 to output the current temperature value data necessary for OSD generation to the OSD generator 40. That is, the microcomputer 10 processes the digital signal according to a preset program and applies an address signal to the OSD generator 40. In this case, the program is typically stored in a memory such as a ROM that is linked with the microcomputer 10.

The OSD generator 40 inputs temperature value data of the microcomputer 10 to generate an OSD corresponding thereto, and the generated OSD is an R.G.B.Y blank signal according to the temperature value data. That is, the OSD generator 40 is composed of a specific font ROM floating several characters and outputs the signal in response to an applied address. The OSD generator 40 is a part well known in a conventional receiver having an on-screen display function. Therefore, when the sensing temperature of the thermal sensor 20 changes, the input of the OSD generator 40 changes accordingly, so that the RGBY blank signal also changes, so the bar 2a shown in FIG. Moved to and displayed.

On the other hand, the video chroma processing unit 50 inputs a composite video signal to the input terminal 2H and performs video chroma processing for output. The output signals are Y, R-Y, B-Y, and G-Y signals, which are luminance signals.

Therefore, the CRT matrix unit 60 combines the output signal of the OSD generation unit 40 and the output signal of the video chroma processing unit 50 to extract each signal, and the output at this time is the temperature value on the original image. The data signal of which data is superimposed as an OSD (On Screen Display Bar) is output.

The video chroma processing unit 50 is the same as a general technical configuration, and a normal video chroma processing unit is a circuit for demodulating a composite video signal to output R-Y, B-Y, G-Y, which are color difference signals.

Therefore, on the CRT 70, the current temperature data is superimposed on the original image to appear as an OSD bar.

Bar 2a of FIG. 2 shows that the current temperature is displayed on the CRT.

The OSD specification is made by the OSD generator 40. If the temperature rises above the currently displayed temperature, the microcomputer 10 outputs the changed output value to the OSD generator 40. The position (2a) on 70) moves in the direction of increasing temperature.

As described above, the present invention has an advantage that the user can know the current temperature while viewing the video screen, since the thermal sensor is attached and the detected temperature value can be displayed on the screen of the CRT. In addition, although the description of the present invention has been described with reference to a temperature sensor, it is possible to attach a humidity sensor and other sensors and apply accordingly to those skilled in the art without departing from the basic definition of the present invention. It is noted that various changes and modifications can be made within the system.

Claims (1)

In the drive circuit for sensing the temperature and displaying the OSD, the microcomputer 10 for processing by a predetermined program to output a control signal for controlling the overall operation of the system and to generate temperature value data in response to an applied digital signal And a heat sensor 20 that senses temperature by the control signal of the microcomputer 10 and generates an electrical signal, and linearly according to the input signal by inputting the output of the heat sensor 20. A linear buffer 30 for outputting a changing digital signal to the microcomputer 10, an OSD generator 40 for inputting temperature data of the microcomputer 10 to generate an OSD signal, and an input terminal 24. The video chroma processing unit 50, the OSD generation unit 40, and the outputs of the video chroma processing unit 50 for chroma processing the chroma signal by inputting the composite image signal are inputted and combined. And a CRT matrix unit (60) for extracting a signal, and a CRT (70) for inputting the extracted signal of the CRT matrix (60) and displaying it on a screen.

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