JPH04127667A - Method for adjusting television receiver - Google Patents

Abstract

PURPOSE:To control the sharpness, the brightness and the contrast corresponding to a visual range and surrounding brightness by detecting the surrounding luminous intensity and controlling the brightness, the contrast and the sharpness according to the detected data and a distance data showing a distance to a viewer. CONSTITUTION:The viewer inputs the distance to television to a microcomputer 14 by operating a key operation part 12. The luminous intensity of a room is detected by a photoelectric sensor 10 and inputted to the microcomputer 14. According to this visual range data and the surrounding luminous intensity detection data, a CPU 14b reads out the control data of the contrast from a memory table for contrast built in a ROM 14c, outputs the read data to a video circuit 16, sets the value of the contrast at an optimum value, reads out respective control data from the similar memory tables for brightness, picture quality and velocity modulation in the ROM 14c and controls them. Thus, the brightness, contrast and the sharpness can be controlled corresponding to the surrounding luminous intensity and the distance to the viewer.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application The present invention relates to brightness (brightness), contrast, and sharpness adjustment of a television receiver.

(b) Conventional technology Traditionally, the brightness of the TV depends on the surrounding brightness.
There are TVs on the market that automatically correct the value to the optimum value.

Furthermore, TVs are on sale in which the viewer inputs the distance between the viewer and the TV into the TV via a remote control, and automatically corrects brightness, sharpness, etc. to optimal values.

(C) Problems to be Solved by the Invention The inventor of the present invention has discovered that the optimal contrast and sharpness values of the TV [i1 side also vary depending on the surrounding brightness, and
We noticed that the optimal value of contrast also changes depending on the distance.

That is, the purpose is to adjust the 3VL of brightness (brightness), contrast, and sharpness according to the surrounding brightness and the distance to the viewer.

(d) Means for solving the problem The present invention detects ambient brightness with a detection means (]0),
It is characterized in that at least brightness, contrast, and sharpness are adjusted using detection data from the detection means (10) and distance data indicating the distance to the viewer.

Further, the present invention provides a method for adjusting a television receiver in which ambient brightness is detected by a detection means (10) and at least brightness and sharpness are adjusted. It is characterized by changing.

(E) Function In the present invention, the optimum value is calculated from the brightness of the room and the viewing distance to the television receiver, and the brightness (Ij degree), image quality (sharpness), contrast, and speed modulation of the screen are calculated using digital signals. (sharpness) to create an optimal screen that is easy to view.

(F) Embodiment A first embodiment of the present invention will be described with reference to FIGS. 1 to 3.

In FIG. 1, (10) is a photoelectric sensor that detects ambient brightness. (12) is 1) a key operation section of the remote controller, which is equipped with buttons (for example, 7-far, ``appropriate'', 1-near) for the viewer to input the distance to T~'. (
14) is a microcomputer that controls each part of the television receiver body. (1, 4a) is an A/D converter that converts the analog voltage value from the photoelectric sensor (10) into digital detection data.

(14b) is a CPU.

(14, c) is a ROM, in which adjustment values for brightness (brightness), contrast, image quality (sharpness), and speed modulation (sharpness) corresponding to detection data and viewing distance data are stored in advance. FIG. 2 shows a memory area for contrast adjustment as a memory table and will be explained. (F), the distance was set in 3 levels, and the brightness detection data was set in 8 levels. Note that the figure shows only the contrast image. In other words, the contrast video control data for all cases is written in the memory table.

(16) in FIG. 1 is a video circuit, which uses video control data from the microcomputer (4) to
Adjust image quality, contrast, brightness, and speed modulation. Regarding image quality, contrast, brightness, and speed modulation, they are well-known circuits, and are also described in 1 of ``rNHK Television Techniques fI# Textbook (Part 1)'' published by Japan Broadcasting Publishing Association on April 10, 1989.
It is also shown in 55P to 158P, 271P, and 272P, and the explanation will be omitted.

The above operation will be explained with reference to FIGS. 1 and 3.

A viewer operates a key operation section (12) to input the distance to the television into a microcomputer (14).

In addition, the brightness of the room is determined by a photoelectric sensor (10).
It is detected and input to the microcomputer (14). This detection signal is converted into digital data by the A/D converter (1, 4a) and input to the CPU (14). C
The P U (14) reads out control data, which is contrast adjustment data, from the contrast memory table (Fig. 2) built in the ROM based on the viewing distance data and the ambient light detection data, and controls the video circuit ( 1
6) and set the contrast value to the optimum value. Further, the CPU (14b) similarly has a ROM (14
Each control data is read out from the memory table for brightness, image quality, and speed modulation in c) and output to the video circuit (16) to perform the remaining three adjustments.

Next, with reference to FIG. 4, writing of control data to the memory table of the ROM (14C) will be explained.

In other words, the optimal control amounts for screen brightness, contrast, image quality, and speed modulation are calculated based on ambient brightness detection data and viewing distance data. In this example, a fuzzy inference method was used to determine the optimal quantity.

Figure 4 shows the fuzzy inference method.

In the graph of FIG. 4(c), the vertical axis represents the control amounts of brightness, image quality, contrast, and speed modulation, and the horizontal axis represents the viewing distance to the television. Based on past experience, this graph shows the membership function that can be changed as shown in this graph.

Furthermore, although the vertical and horizontal directions are reversed in FIG. 4(b), the horizontal axis represents each control amount and the vertical axis represents the brightness of the room, and similarly shows the membership function.

In Figure 4 (a), the vertical axis is the brightness of the room (corresponding to the graph in b), and the horizontal axis is the viewing distance (corresponding to the graph in c).Here, the reference point is set at the top left where the room is the brightest. For a place where the viewing distance is far, the optimal control amount is determined in all cases by inference from the graphs b and C. In this case, if the viewing distance is sampled in 3 stages and the brightness of the room is sampled in 8 stages, one control amount is obtained. 3x8=24 pieces of data are created.In this case, there are 4 types of control amounts, so 24x
Since 4=96 pieces of data are created, it is stored in the ROM of the microcomputer.

The four video control data determined in this manner are output as digital signals to the video circuit (16) to control the screen in an optimal state.

Until now, there has been no TV in which the television receiver sets the optimal screen condition in response to changes in the environment, such as the brightness of the room or the viewing distance to the TV.

In the present invention, the microcomputer (14) uses data determined by experience to deal with these two changing factors.
controls the screen and can achieve the optimal screen condition at any time.

By the way, in a television receiver, when a weak electric field is received, a noise screen appears and the quality of the screen deteriorates. Therefore, a noise reduction circuit is operated to remove noise.

Methods for this removal include, for example, attenuating the high frequency components of the video signal by adjusting the image quality, increasing the clip level to remove minute luminance signals (noise), or
Various examples can be considered, such as increasing the feedback amount of the field or one-frame recursive noise reducer.

By the way, in the TV shown in FIG. 1, if this noise reduction is not activated, the screen will naturally change, and correction will be required to match this screen.

Such an example will be explained with reference to FIGS. 5 to 7.

When the noise reduction function is activated, the microcomputer software is programmed so as not to change the amount of control such as image quality and speed modulation.

In other words, when noise reduction is activated, the amount of image quality control such as image quality and speed modulation does not change due to environmental changes such as room brightness.

This allows the noise reduction function to work fully, allowing the user to view the screen with less noise at any time.

FIG. 5 is a circuit diagram, and the same parts as in FIG. 1 are given the same symbols. (12) is a key operation unit provided with a noise reduction on/off key.

(14d) is a display circuit that displays "Noise Hunter On" on the TV screen as shown in FIG. 6 when the noise reduction is turned on. The microcomputer (14) outputs control data for noise reduction on/off in addition to conventional control data for image quality, speed modulation, contrast, and brightness to the video circuit (16).

Next, the operation will be explained with reference to FIG. 5 and FIG. 7 showing a flowchart. In addition, in order to simplify the explanation,
We have omitted an explanation of the amount of screen control based on viewing distance data. When noise reduction is off, A,/
When the data from the D converter ( ], 4a) has a data value indicating that the room is dark, the microcomputer (14) outputs control data so as to control all of the brightness, contrast, image quality, and speed modulation of the screen to be low.

When the noise reduction is turned on by the key operation unit (12), the frequency characteristics of the video circuit are lowered by +1 m.
? The microcomputer outputs digital control data to the video circuit (16). Since this alone cannot sufficiently suppress screen noise, the speed modulation value of the digital control data is fixed at a high value, the image quality value is fixed at a low value, and the same is output to the video circuit (16) as digital data.

That is, in this embodiment, when noise reduction is turned on, the screen image quality and speed modulation settings are not changed in response to changes in room brightness, but only the brightness and contrast are changed.

The noise reduction function that suppresses screen noise in television receivers becomes effective by changing not only the frequency characteristics of the video circuit, but also the image quality and speed modulation. but,
When changing the image quality and speed modulation depending on the brightness of the surroundings, the noise reduction function may not work sufficiently due to the influence of the function. Here, in this example, when noise reduction is activated, the values of control data for image quality and speed modulation are fixed to values that provide the best noise reduction function.

In the above embodiment, the sharpness-related image quality and speed modulation are fixed when noise reduction is turned on, regardless of the surrounding brightness, but they may also be fixed regardless of the viewing distance.

Also, I fixed the control data for image quality and speed modulation, but if the memory has a large capacity, it will be easier to use when noise reduction is turned on. , control may be performed based on this.

(G) Effects of the Invention As described above, according to the present invention, sharpness, brightness, and contrast can be controlled according to viewing distance and surrounding brightness.

Further, according to the present invention, an optimal screen can be viewed even when noise reduction is turned on.

[Brief explanation of drawings]

1 to 3 relate to a first embodiment of the present invention; FIG. 1 is a schematic diagram, FIG. 2 is a memory table, and FIG. 3 is a flowchart. FIG. 4 is a diagram for explaining fuzzy inference. 5 to 7 relate to a second embodiment of the present invention, in which FIG. 5 is a schematic block diagram, FIG. 6 is a diagram showing a screen, and FIG. 7 is a diagram showing a flowchart. (10)...Photoelectric sensor (detection means), (14)
...Microcomputer, (14c)...RO
M, (12)...Key operation unit, (16)...Video circuit.

Claims (5)

[Claims] (1) The surrounding brightness is detected by the detection means (10), and at least the brightness, contrast, and sharpness are adjusted based on the detection data from the detection means (10) and distance data indicating the distance from the viewer. Features: How to adjust a television receiver. (2) The method for adjusting a television receiver according to claim 1, wherein the sharpness is performed by a speed modulation circuit. (3) The method for adjusting a television receiver according to claim 1 or 2, wherein the sharpness is performed by an image quality adjustment circuit. (4) In an adjustment method for a television receiver in which ambient brightness is detected by the detection means (10) and at least brightness and sharpness are adjusted, the sharpness adjustment value is changed when the noise removal circuit is operating. 2. The method of adjusting a television receiver according to claim 1. (5) The method for adjusting a television receiver according to claim 4, wherein the sharpness adjustment value is fixed when the noise removal circuit is operating.