JPH07115566A - Gamma correction circuit - Google Patents

Abstract

PURPOSE:To provide the gamma correction circuit with a small circuit scale and excellent characteristic. CONSTITUTION:The circuit is provided with selectors 7, 8 which select a 1st correction means when an input video signal 11 is higher than offset data 13 as the result of comparison of a comparator 1 and select a 2nd correction means when the input video signal 11 is lower than the offset data 13, and the 1st correction means consists of a subtractor 4, a multiplier 15 and an adder 6 and the 2nd correction means is made up of a ROM 2 storing only a correction value corresponding to the input video signal 11 smaller than the offset data 13 and an adder 5.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a .gamma. Correction circuit in an image pickup system such as a video movie.

[0002]

2. Description of the Related Art In an image pickup system, the brightness (brightness / darkness) of an image signal output from a video tube is proportional to the square of the value of the input image signal due to its characteristics. Due to such characteristics of the video tube, when the output video signal is viewed as it is, the brightness of the video seems to change unnaturally. Therefore, in general, the output video signal from the video tube is corrected through a correction circuit so as to obtain a natural video. The correction at this time is called γ correction, and the circuit used at this time is called a γ correction circuit.

Without γ correction, the brightness level of the video signal output from the video tube is approximately the brightness level of the output signal = α × (the brightness level of the input signal).
² However, α has a constant relationship.

Therefore, as shown in FIG. 5, the γ correction circuit is configured so that the input video signal of the γ correction circuit = β × (the output video signal of the γ correction circuit) ⁻² , where β is a constant. Has been done.

As a conventional γ correction method for a video signal, a method using a γ correction circuit having a read-only storage device (hereinafter referred to as ROM) 102 as shown in FIG. 3 or a subtractor 104 as shown in FIG. 4 is used. A method of using a γ correction circuit composed of a multiplier 115, an adder 106, and the like is generally known.

One of the conventional γ correction circuits will be described with reference to the block diagram showing the configuration of the γ correction circuit in FIG. 3 and the diagram showing the relationship between the input video signal and the output video signal of the γ correction circuit in FIG. To do.

The γ correction circuit shown in FIG. 3 is composed of a ROM 102, and the ROM 102 stores all output video signals corresponding to input video signals of respective brightness levels. When an input video signal (hereinafter, the input video signal is also denoted by reference numeral 111) is input to the ROM 102 from the input video terminal 111, an output video signal corresponding to the brightness level of the input video signal 111 is output from the output video terminal 112. It is output (hereinafter, the output video signal is also denoted by reference numeral 112).
The luminance level of the output video signal corresponding to the input video signal stored in the ROM 102 has a relationship of output video signal) = β × (input video signal) ⁻² as shown in FIG. Therefore, the γ correction circuit shown in FIG. 3 can correct a natural video signal.

Next, another conventional γ correction circuit is shown in FIG.
6 is a block diagram showing the configuration of the γ correction circuit of FIG.
The correction circuit will be described with reference to the diagram showing the relationship between the input video signal and the output video signal.

According to the γ correction circuit shown in FIG. 4, correction can be performed in a polygonal line, and for some input video signal values, corresponding output video signal values are predetermined. For example, points A, B, C, ... In FIG.
The value of the output video signal is determined in advance with respect to the value of the input video signal. Then, correction is made in a polygonal line based on these points.

As shown in FIG. 4, the multiplexer 120
Are output lines 11 according to the value of the input video signal 111.
The configuration is such that one is selected from 6a, 116b, 116c, .... Then, each output line 11
A subtractor 104, a multiplier 115, and an adder 106 are connected in series to 6a, 116b, 116c, ... And connected to a multiplexer 121 as an input line 118.
Further, the multiplexer 121 has the output video terminal 112.
(Hereinafter, the output video signal is also denoted by reference numeral 112).

Further, reference input value input terminals 113a, 11
3b, 113c, ...
3) is assigned to each of the corresponding subtractors 104a, 10a.
4b, 104c, ..., and reference output value input terminals 122a, 122b, 122c ,.
06a, 106b, 106c, ... The multiplication data input terminals 114a, 114b, 114c ... (Hereinafter, the multiplication data is also denoted by reference numeral 114) are connected to the corresponding multipliers 115a, 115b, 115c ,.

The operation of the γ correction circuit configured as described above will be described with reference to FIGS. 4 and 6.

Reference input values 113a, 113b, 113
The values of c, ... Are points A, B, and C shown in FIG. 6, respectively.
Are the luminance levels of the input video signals, and the reference output values 122a, 122b, 122c, ... Are the luminance levels of the output video signals of points A, B, C ,. In addition, the multiplication data 114a, 114b, 114
The values of c, ... Are equal to the inclination between AB, the inclination between BC, the inclination between CD, ... In addition, these,
Reference input value 113, reference output value 122, multiplication data 11
An appropriate value for 4 is determined in advance.

First, the operation of the γ correction circuit at points A to B in FIG. 6 will be described. When the brightness level of the input video signal 111 is in the range from point A to point B, the multiplexer 120
Selects the output line 116a. Then, the input video signal 1
11 is input to the subtractor 104a via the multiplexer 120. Further, the luminance level of the reference input value 113a at this time is equal to the luminance level of the input video signal 111 at the point A and is 0, so that the subtracter 104a subtracts the reference input value from the input video signal 111 from the input video signal 111. 11
3a is subtracted by the value (0), and the result is multiplied by the multiplier 11
5a is input. In the multiplier 115a, the subtractor 104a
Is multiplied by the multiplication data 114a (value of inclination between AB), and the multiplication result is added by the adder 106.
Input to a. The adder 106a adds the signal brightness level from the multiplier 115a and the reference input value 122a.
The reference output value 122a at this time is equal to the brightness level of the output video signal 111 at the point A and is 0, so that the adder 1
At 06a, the value (0) of the reference output value 122a is added. Then, the addition result is input to the multiplexer 121 through the input line 118a. The input line 118 a is selected in the multiplexer 121, and the input line 118 a becomes the output video signal 112 as it is.

Input video signal 111 of other brightness levels
The same correction is also applied to. For example, when the brightness level of the input video signal 111 is in the brightness level range from point B to C, the multiplexer 120 selects the output line 116b, and when the input video signal 111 is in the brightness level range from point C to D, the multiplexer is selected. Reference numeral 120 selects the output line 116c, and the same correction as in the brightness level range from point A to point B is performed. As a result, by using the γ correction circuit shown in FIG. 4, the input video signal 111 shown in FIG.
And the output video signal 112 are obtained.

[0016]

Among the two types of conventional γ correction circuits described above, in the γ correction circuit shown in FIG. 3, the output video signals 112 corresponding to the input video signals 111 of all luminance levels are output. Since the data is stored in the ROM 102, ideal γ correction can be performed. However, the input video signal 111 of all brightness levels
Regarding the above, since the data of the corresponding output video signal 112 is stored, there is a problem that the ROM capacity becomes very large and the circuit scale becomes large.

Further, since the γ correction circuit described with reference to FIG. 4 employs a method of approximating with a polygonal line, in order to obtain the output video signal 112 which is not unnatural to the eyes, many subtractors 104 are used. , The multiplier 115, the adder 106, etc. are required, and the circuit scale becomes large. on the other hand,
If the number of the subtracters 104, the multipliers 115, and the adders 106 is reduced, the circuit scale can be reduced. However, the smaller the number of the subtractors 104, the smoother the correction becomes, and the unnatural output is generated. Since it becomes the video signal 12, there is a limit in reducing the circuit scale.

The present invention solves the above-mentioned problems. The circuit scale is small and an output video signal with high characteristics can be obtained.
The purpose is to provide a correction circuit.

[0019]

In order to achieve the above object, the present invention provides a first aspect in which a comparison result of a comparator for comparing an input video signal and a reference value is larger when the input video signal is larger.
And a selector that selects the second correction means when the input video signal is smaller, and selects the first correction means or the second correction means when the input video signal and the reference value are equal. The first correction means includes a subtracter, a multiplier, and an adder, and the second correction means has a storage device in which the correction value is stored.

[0020]

According to the present invention, when the input video signal is larger than the reference value, the correction means constituted by the subtractor, the multiplier and the adder performs the correction according to the above-mentioned structure. The constituent subtractor, multiplier, and adder can each be one. Further, when the input video signal is smaller than the reference value, correction is performed by the correction means having a storage device, so that only the correction value corresponding to the input video signal smaller than the reference value needs to be stored in the storage device. The capacity of the storage device can be reduced.

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The configuration of an embodiment of the .gamma. Correction circuit of the present invention will be described below with reference to the block diagram shown in FIG.

As shown in FIG. 1, reference numeral 1 denotes a comparator, which is an input signal from an input video terminal 11 (hereinafter, the input video signal is also denoted by reference numeral 11) and a predetermined reference luminance level (hereinafter, offset). (Represented as data) and the size. Reference numeral 7 is a selector which selects either one of the output lines 16 and 17 according to the comparison result of the comparator 1. Reference numeral 8 is also a selector which selects one of the input lines 18 and 19 according to the comparison result of the comparator 1. Reference numeral 2 is a ROM in which the correction value of the input video signal 11 is stored. Reference numeral 4 is a subtractor, 5 and 6 are adders, and 15 is a multiplier. Reference numeral 12 is an output video terminal (hereinafter, output video signal is also denoted by reference numeral 12), and 13 is offset data input terminal (hereinafter, offset data is also denoted by reference numeral 13). Reference numeral 14 denotes a multiplication data input terminal (hereinafter, the multiplier data is also denoted by reference numeral 14).

The input video terminal 11 is connected to the selector 7, the output line 16 of the selector 7 is connected to the adder 5 directly and via the ROM 2, and the adder 5 is connected via the input line 18 to the selector 5. 8 is connected. The other output line 17 of the selector 7 is connected to the subtractor 4, and the subtractor 4 is connected to the multiplier 15. And the multiplier 1
5 is further connected to the adder 6, which adds the input line 19
It is connected to the selector 8 via. The selector 8 is connected to the output video terminal 12. The input video terminal 11 is also connected to the comparator 1, and the comparator 1 is connected to the selectors 7 and 8. The offset data input terminal 13 is connected to the comparator 1, the subtractor 4 and the adder 6, and the multiplication data input terminal 14 is connected to the multiplier 15.

Next, regarding the operation of the γ correction circuit of this embodiment shown in FIG. 1, the input video signal 11 and the output video signal 12
This will be described with reference to FIG. 2 showing an example of the relationship with.
It should be noted that all the luminance levels of the signals in this embodiment are expressed in hexadecimal notation, and in the case of hexadecimal notation, the value of the luminance level is followed by (hex).

In FIG. 2, when the offset data 13 is the brightness level 80 (hex), the multiplication data 14 is 0.5, and the input video signal 11 is the brightness level 40 (hex), the correction value is the brightness level 24 (hex). The relationship between the input video signal 11 and the output video signal 12 is shown. Actually, the correction values when the input video signal 11 has other brightness levels are also determined in advance, and the respective correction values are stored in the ROM 2, but they correspond to the input video signals 11 having other brightness levels. The same applies to the correction value to be set.

If the brightness level of the output video signal 12 is too high with respect to the brightness level of the input video signal 11, the screen suddenly becomes bright, and the output video signal 12 has a brightness level higher than that of the input video signal 11. If the brightness level is too low, you may feel that the screen suddenly goes dark. Optimal values are determined in advance for the offset data 13, the multiplication data 14, and the correction value in this embodiment.

In FIG. 2, in the range where the luminance level of the input video signal 11 is less than 80 (hex), the luminance level of the input video signal 11 is smaller than that of the offset data 13 [80 (hex)]. The correction value stored in the ROM 2 shown in FIG. 1 is added to 11 to perform γ correction, and the output video signal 12 is obtained. Further, in the range where the input video signal 11 is larger than 80 (hex), the input video signal 11 from the offset data 13 [80 (hex)]
Has a larger value, the γ correction is performed so that the input video signal 11 and the output video signal 12 have a proportional relationship based on the time when the input video signal 11 is the offset data 13 [80 (hex)], and the output is performed. The video signal 12 is obtained.

Next, the operation of the γ correction circuit shown in FIG. 1 will be described with reference to FIGS. 1 and 2.

The input video signal 11 is input to the comparator 1,
Therefore, the magnitude of the input video signal 11 and the offset data 13 are compared. The operation of the γ correction circuit when the comparison result of the input video signal 11 is smaller than that of the offset data 13 will be described below.

The comparator 1 controls the selectors 7 and 8 so that the selector 7 selects the output line 16 and the selector 8 selects the input line 18. The input video signal 11 input to the selector 7 is input to the ROM 2 and the adder 5 via the output line 16. The ROM 2 outputs a correction value corresponding to the input video signal 11 to the adder 5. In the adder 5, the input video signal 11 output from the selector 7 and the correction value corresponding to the input video signal 11 output from the ROM 2 are added, and the addition result is input to the selector 8 via the input line 18. . In the selector 8, the input line 18 is selected by the comparator 1, and the input line 18 becomes the output video signal 12 as it is.

For example, if the input video signal 11 has a brightness level of 4
If it is 0 (hex), it is smaller than the luminance level 80 (hex) of the offset data 13, so that the luminance level 40
The value of (hex) is input to the ROM 2 and the adder 5. Furthermore, from the ROM2, a brightness level of 40 (hex)
The correction value 24 (hex) corresponding to is output to the adder 5. Brightness level 40 (hex) and correction value 24 in adder 5
(Hex) is added, and the brightness level of the addition result is 64
(Hex) is input to the selector 8 through the input line 18.
Therefore, the input video signal 11 has a brightness level of 40 (he
x), the output video signal 1 corrected by the γ correction circuit
2 has a brightness level of 64 (hex).

Input video signal 1 from offset data 13
When 1 is small, the correction means including the ROM 2 and the adder 5 similarly corrects other brightness levels. The relationship between the input video signal 11 and the output video signal 12 having other brightness levels is as shown in FIG.

Next, the operation of the γ correction circuit when the comparison result of the input video signal 11 is larger than that of the offset data 13 will be described. In this case, the comparator 1 is the selector 7
Controls the output line 17 and the selector 8 controls the selectors 7 and 8 so as to select the input line 19. Selector 7
The input video signal 11 that has been input to is input to the subtractor 4 via the output line 17. Offset data 1 for the subtractor 4
3 is also input, the luminance level of the offset data 13 is subtracted from the signal of the output line 17, and the subtraction result is output to the multiplier 15. The multiplication data 14 is also input to the multiplier 15, which multiplies the input signal from the subtractor 4 and the value of the multiplication data 14 and outputs the multiplication result to the adder 6. Offset data 13 is also input to the adder 6, where the offset data 13 and the input signal from the multiplier 15 are added. Then, the output signal from the adder 6 becomes the output line video signal 12 as it is.

For example, if the input video signal 11 has a brightness level F
8 (hex), the value of the input video signal 11 is higher than the value brightness level 80 (hex) of the offset data 13, so the value of the brightness brightness level F8 (hex) is the subtracter 4
Entered in. In the subtractor 4, the brightness level F8 (hex)
To offset data 13 [luminance level 80 (he
x)] is subtracted, and the subtraction result luminance level 78 (he
x) is input to the multiplier 15. In the multiplier 15, the brightness level 78 (hex) from the subtractor 4 and the multiplication data 0.5
And are multiplied, resulting in a brightness level of 3C (hex). Then, the multiplication result is input to the adder 6. The value of the multiplication data 14 is the slope of a straight line representing the relationship between the input video signal 11 and the output video signal 12 when the brightness level of the input video signal 11 is higher than the brightness level of the offset data 13, and It has been decided. That is, in the present embodiment, the value of the multiplication data 14 changes from the signal luminance level of 80 (hex) to FF (he).
It becomes the slope of the straight line up to x). The adder 6 adds the multiplication result brightness level 3C (hex) and the brightness level 80 (hex) of the offset data 13, and the addition result brightness level BC (hex) is input to the selector 8 through the input line 19. Therefore, the input video signal 11 has the brightness level F8.
When (hex), the output video signal 12 is corrected by the γ correction circuit to have the brightness level BC (hex).

When the brightness level of the input video signal 11 is higher than the brightness level of the offset data 13, the correction means composed of the subtractor 4, the multiplier 15 and the adder 6 also applies to the other brightness levels. It will be corrected. The relationship between the input video signal 11 and the output video signal 12 at that time is as shown in FIG.

In the first embodiment of the present invention, one of the correction means is composed of the ROM 2 and the adder 5 for storing the correction value corresponding to the input video signal 11, If the value of the output video signal 12 corresponding to the video signal 11 is stored in the ROM 2 as a correction value, the adder 5
Need not be configured.

Further, the offset data 13 of the first embodiment of the present invention adopts a value when the values of the input video signal 11 and the output video signal 12 are equal, but it is not always necessary. When the values of the input video signal 11 and the output video signal 12 of the offset data 13 are different, only the value of the offset data 13 input to the adder 6 is used as the output video signal 1 corresponding to the input video signal 11 of the offset data 13.
If you enter a value of 2, there is no problem.

As described above, according to the γ correction circuit of the embodiment of the present invention, the γ correction is performed by using the ROM 2 or the like at the low luminance level, so that the ROM 2 corresponds to the input video signal 11 smaller than the offset data 13. Since it is sufficient to store only the correction value to be stored, the capacity of the ROM 2 can be considerably reduced. Further, at the high brightness level, since the correction means composed of the subtractor 4, the multiplier 15, and the adder 6 is used to perform the correction having the proportional relationship, the subtractor, the multiplier, and the adder are Each can be composed of one. Therefore, the circuit scale can be considerably reduced.

In addition, since correction is performed by the correction means having the ROM 2 at a low luminance level where a linear γ correction produces an unnatural image, a visually excellent correction can be performed.

[0040]

According to the present invention, when the input video signal has a low luminance level, the gamma correction of the input video signal is performed with the correction value stored in the storage device, and when the input video signal has a high luminance level, the linear correction is performed. Therefore, it is possible to perform a visually natural correction with a small circuit scale.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a γ correction circuit according to an embodiment of the present invention.

FIG. 2 is a diagram showing a relationship between an input video signal and an output video signal of a γ correction circuit of the present invention.

FIG. 3 is a block diagram showing a configuration of a conventional γ correction circuit.

FIG. 4 is a block diagram showing a configuration of a conventional γ correction circuit.

FIG. 5 is a diagram showing a relationship between an input video signal and an output video signal of a conventional γ correction circuit.

FIG. 6 is a diagram showing a relationship between an input video signal and an output video signal of a conventional γ correction circuit.

[Explanation of symbols]

 1 comparator 2 read-only storage device (ROM) 4 subtractor 5 adder 6 adder 7 selector 8 selector 11 input video terminal 12 output video terminal 13 offset data input terminal 14 multiplication data input terminal 15 multiplier 16 and 17 output line 18,19 Input line

Claims (2)

[Claims] 1. A first and a second correction means for correcting an input video signal, a comparator for comparing the input video signal and a reference value, and the comparator when the comparison result of the comparator is larger for the input video signal. The first correction means is selected, and when the input video signal is smaller, the second correction means is selected, and when the input video signal and the reference value are equal, the first correction means or the second correction means is selected. And a selector for selecting, the first correction means includes a subtractor, a multiplier, and an adder, and the second correction means has a storage device in which a correction value is stored. Correction circuit. 2. The gamma correction circuit according to claim 1, wherein the second correction means is composed of a storage device and an adder.