JP2008104016A - Gradation correction device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gradation correction device capable of guaranteeing operation processing of a gradation correction signal in real time even without using a high-speed computing element. <P>SOLUTION: The gradation correction device is provided with: a histogram memory 2 for preparing a luminance distribution of input video signals; an arithmetic unit 3 for calculating gradation correction data in the next frame from data of the histogram memory; and a lookup table memory 4 for storing the gradation correction data, wherein a series of signal processing being preparation of the luminance distribution, operation of the gradation correction data, and gradation correction by the gradation correction data is performed sequentially for every area in which the input video signal is divided in a vertical scanning direction. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a gradation correction device used for correcting gradation of a video signal, such as a television receiver, a video tape recorder, a video camera, and a video disk.

  In recent years, with the increase in size and quality of color television receivers, in order to make the image appear clearer, the gradation is corrected by passing the video signal through a nonlinear amplifier, and the dynamic range of the video on the monitor is increased. The importance of expanding gradation correction technology is increasing.

  As a gradation correction apparatus that performs such gradation correction, an apparatus that uses a gradation correction signal created from an image signal of the previous frame for gradation correction of the next frame is known.

  FIG. 3 is a block diagram showing a circuit configuration of such a conventional gradation correction apparatus. In this gradation correction apparatus, the A / D converter 1 converts the input video signal a into a luminance signal i as digital data. A luminance histogram p is extracted from the luminance signal i in the histogram memory 2. From this luminance histogram p, look-up table data t for gradation correction is generated by the arithmetic unit 3 constituted by a microcomputer. This look-up table data t is input to the look-up table memory 4 and temporarily stored using the converted input signal h (luminance signal i) as an address. Then, when the conversion input signal h ′ (the luminance signal i of the next frame) is given to the lookup table memory 4, data for the address is output as the corrected output luminance signal m. The corrected output luminance signal m is converted into an analog signal by the D / A converter 5 and becomes an output signal d. These signal processes are controlled by the timing control circuit 6.

Next, the operation timing of each circuit that executes the series of signal processing will be described with reference to FIG. Here, a case is shown in which the input video signal 12 of the Nth frame is subjected to gradation correction. From the input video signal 11 of the (N−1) th frame, which is a frame 1V before the Nth frame to be subjected to gradation correction, the histogram memory 2 stores the luminance histogram p within this (N−1) th frame period. An extraction process 14 is performed. Further, the calculation process 15 of the lookup table data t is performed by the calculation device 3 in the blanking period 13 between the (N−1) th frame period and the Nth frame period. Based on the obtained look-up table data t, the memory conversion process 16 is performed by the look-up table memory 4 in the N-th frame period, and the video signal output process 17 of the N-th frame is performed.
JP-A-3-126377

  However, in the conventional gradation correction device, as shown in the timing chart of FIG. 4, the conversion process from the luminance histogram p to the look-up table data t in the arithmetic device is performed with the (N−1) th frame and the first. It must be completed in the blanking period 13 with N frames. In particular, the luminance histogram and the look-up table data are enormous amounts at the present time when the large screen image quality has been improved. Therefore, in order to complete these conversion processes within a predetermined period, it is necessary to mount a high-speed computing unit, resulting in an increase in circuit scale and cost.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a gradation correction apparatus capable of guaranteeing real-time processing of a gradation correction signal without using a high-speed arithmetic unit.

  In order to achieve this object, a gradation correction apparatus according to the present invention includes a histogram memory that creates a luminance distribution of an input video signal, and an arithmetic apparatus that calculates gradation correction data in the next frame from the data in the histogram memory. And a look-up table memory for storing the gradation correction data, and a series of signal processing including creation of the luminance distribution, calculation of the gradation correction data, and gradation correction by the gradation correction data, It has a timing control circuit for controlling the timing of the series of signal processing so that the input video signal is sequentially performed for each of the divided areas in the vertical scanning direction.

  According to the present invention, since a series of signal processing for obtaining a gradation correction signal can be performed by dividing the input video signal into a plurality of regions divided in the vertical scanning direction, each processing time is increased. The circuit scale can be reduced because it is not necessary to mount a high-speed computing unit to guarantee real time.

  The gradation correction apparatus of the present invention further includes a horizontal sync counter that counts horizontal blanking of the input video signal, and the timing control circuit determines the division timing of the input video signal in the vertical scanning direction. It is preferably determined by a counter. Further, it is preferable that the series of signal processing is sequentially performed for each region obtained by dividing the input video signal into two in the vertical scanning direction.

  Hereinafter, specific embodiments of the gradation correction apparatus of the present invention will be described with reference to the drawings.

  FIG. 1 is a block diagram showing a schematic configuration of a gradation correction apparatus 10 according to an embodiment of the present invention. As shown in FIG. 1, the gradation correction device 10 according to the present embodiment includes an A / D converter 1, a histogram memory 2, an arithmetic device 3, a look-up table memory 4, a D / A converter 5, and a timing control circuit. 6 and a horizontal sync counter 7. The arithmetic device 3 is composed of a microcomputer.

  In the gradation correction apparatus 10, the A / D converter 1 converts the input video signal a into digital data and outputs a luminance signal i. A luminance histogram p is extracted from the luminance signal i in the histogram memory 2. The gradation correction apparatus 10 includes a horizontal sync counter 7 in order to perform a series of signal processing starting from the extraction of the luminance histogram p for each region obtained by dividing the input video signal a in the vertical direction. The horizontal sync counter 7 counts the number of horizontal blanking of the luminance signal i and sends a control signal for dividing the timing of signal processing to the timing control circuit 6 based on the count result.

  The arithmetic unit 3 generates look-up table data t for gradation correction from the luminance histogram p. This lookup table data t is input to the lookup table memory 4 and temporarily stored at an address indicated by the conversion input signal h (luminance signal i). When the converted input signal h ′ (luminance signal i of the next frame) is given to the lookup table memory 4, the data stored at the address indicated by the converted input signal h ′ is output as the corrected output luminance signal m. Is done. This point is the same as the conventional gradation correction apparatus shown in FIG. However, in the gradation correction apparatus of the present embodiment, these series of signal processing are performed for each area on the input video signal divided into a plurality of parts in the vertical direction based on the count result of the horizontal sync counter 7. Is called.

  In the present embodiment, the arithmetic unit 3 generates the lookup table data t by multiplying the luminance histogram p by a normalization coefficient and performing a cumulative calculation of the normalized histogram data. However, the process in which the arithmetic unit 3 generates the lookup table data t from the luminance histogram p is not limited to this specific example, and a known process can be applied. For example, smoothing such as an average value filter and a median filter is performed on the histogram data, and the average value of the input luminance signal, mode value, maximum value, minimum value, deviation coefficient, white area, The black area, etc. is detected, and from these data, the limiter value, addition value, subtraction value, cumulative start luminance level, cumulative stop luminance level, and maximum output level are determined, and the histogram data is cumulatively calculated. Can be obtained.

  A state of such a series of signal processing will be specifically described with reference to FIG.

  FIG. 2 is a timing diagram when the input video is divided into two vertical regions of the upper half and the lower half, that is, when the arithmetic unit 3 is activated at the vertical center of the input video signal. First, in the gradation correction device 10, while the upper half video signal 11 a of the (N−1) th frame is being input, the histogram memory 2 uses the luminance histogram p of the upper half of the input video from the video signal 11 a. The detection process 14a is performed. Next, while the lower half video signal 11b of the (N-1) th frame is being input, the histogram memory 2 performs the luminance histogram p detection process 14b of the lower half area of the input video from the video signal 11b. Done. In parallel with the detection process 14b, the calculation device 3 performs the calculation process 15a of the look-up table data t for the upper half area of the input video. Then, in the blanking period 13, the calculation process 15 b of the lookup table data t in the lower half area is started. At this time, the calculation process 15 a in the upper half area is almost completed, and the lookup table memory In this state, the memory conversion process 16a in 4 can be started immediately. Then, as a result of the gradation correction performed by the lookup table memory 4, while the video signal output process 17 a for the upper half of the Nth frame is being performed, the lower half of the Nth frame is performed in the arithmetic unit 3. The calculation processing 15b for the area is completed. Then, the memory conversion process 16b is performed by the look-up table memory 4 on the video signal in the lower half area of the Nth frame obtained in the calculation process 15b. Thus, the video signal output processing 17b is performed as a result of the gradation correction based on the input video signal of the (N-1) th frame for the lower half area of the Nth frame.

As described above, in the gradation correction apparatus 10 of the present embodiment, the horizontal sync counter 7 detects the video period during the input gradation correction, and divides the image period into an upper half area and a lower half area, thereby correcting the gradation. Perform a series of processes for. That is, the horizontal sync counter 7 detects the time (T ₁ shown in FIG. 2) when the input of the upper half video signal of the (N−1) th frame is finished, and the timing control circuit 6 detects the time T _{1 at} this time T ₁ . The arithmetic processing 15a in the arithmetic device 3 is started. Thereby, the processing time for the software calculation time in the arithmetic unit 3 can be increased.

  In the above description, an example in which one frame is divided into an upper half area and a lower half area is shown. However, the present invention is not limited to this, and the upper end 1/3, the center 1/3, and the lower end 1/3. It is also possible to set the number of divisions to three or more, such as three divisions.

  Compared to the case where the conversion process from the luminance histogram to the look-up table data is completed during the blanking period as in the prior art, one frame is divided into two as in the gradation correction apparatus 10 of the present embodiment. In this case, a time corresponding to half of the video active period can be used as the calculation time. However, when processing one frame in two as described above, the division position of the input video for obtaining the lookup table corresponds to the center of the screen. On the other hand, if one frame is divided into three areas, for example, the upper end 1/3, the center 1/3, and the lower end 1/3 as described above, and the lookup table is obtained, the human screen gaze point is Since it is usually at the center of the screen, there is an advantage that an optimum lookup table is required for the image at the center of the screen that the observer pays most attention to.

  When displaying a 16: 9 content (for example, a movie) on a monitor having a width to height ratio of 4: 3, a black display portion exists at the upper limit of the screen. In this case, if the input video signal is divided into three parts at a ratio of 1: 2: 1 from the top in the vertical direction, there is an advantage that the lookup table in the center of the screen can be optimally created.

  When the number of pixels in the vertical direction is 720, the blanking period is 30 lines with respect to the video active period (720 lines). For this reason, for example, if an algorithm capable of completing the calculation in the blanking period (30 lines) as in the prior art is implemented, the lookup table can be calculated by dividing the input video signal into a maximum of 24. is there.

  Further, in the present invention, if the image after gradation correction is unnatural at the time of switching of the look-up table data t that is a divided portion by performing the division process in one frame, the look-up table data t It is also possible to reduce this unnaturalness by applying a low pass filter to the output video in the vicinity of the switching part.

  According to the gradation correction device according to the present invention, as described above, the input video signal is divided into a plurality of vertical regions, and a series of signal processing is performed to create a gradation correction signal for each of the regions. An allowance can be made for the calculation processing time. Thereby, real-time processing can be guaranteed without complicating the circuit configuration. For this reason, it can be suitably used in video receivers that receive digital television broadcasts, HD video tape recorders, video cameras, video disks, and the like.

  INDUSTRIAL APPLICABILITY The present invention can be industrially used as a gradation correction apparatus that can guarantee real-time processing without complicating the circuit configuration.

The block diagram of the gradation correction apparatus in the Example of this invention The figure which shows the processing timing of the gradation correction apparatus in the Example of this invention. Block diagram of a conventional tone correction device The figure which shows the processing timing of the conventional gradation correction apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 A / D converter 2 Histogram memory 3 Arithmetic unit 4 Look-up table memory 5 D / A converter 6 Timing control circuit 7 Horizontal sync counter 10 Gradation correction device 11 N-1 frame signal input period 11a N-1 frame Upper half signal input period 11b Lower half signal input period of N-1 frame 12 N frame signal input period 12a Upper half signal input period of N frame 12b Lower half signal input period of N frame 13 Blanking period 14 Histogram Memory detection period 14a Histogram memory detection period for upper half image area 14b Histogram memory detection period for lower half image area 15 Correction signal calculation period 15a Correction signal calculation period for upper half image area 15b Correction signal for lower half image area Calculation period 16 Look-up memory conversion period 16a Look-up memory conversion period for upper half image area 16b Look-up memory conversion period for lower half image area 17 N frame video signal output period 17a N-frame video signal output period for upper half image area 17b Lower half image Region N frame video signal output period

Claims (3)

  A histogram memory for creating a luminance distribution of an input video signal; an arithmetic unit for calculating gradation correction data in a next frame from the data of the histogram memory; and a lookup table memory for storing the gradation correction data. A series of signal processing including creation of the luminance distribution, calculation of the gradation correction data, and gradation correction based on the gradation correction data is sequentially performed for each region obtained by dividing the input video signal into a plurality of vertical scanning directions. A gradation correction apparatus having a timing control circuit for controlling the timing of the series of signal processing.   The horizontal sync counter that counts the horizontal blanking of the input video signal is further provided, and the timing control circuit determines the division timing of the input video signal in the vertical scanning direction by the horizontal sync counter. Gradation correction device.   The gradation correction apparatus according to claim 1, wherein the series of signal processing is sequentially performed for each region obtained by dividing the input video signal into two in the vertical scanning direction.

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