JP3865975B2 - Video signal correction circuit - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a video signal correction technique for correcting a video signal so that display on a screen of a display device such as a CRT display is optimized.
[0002]
[Prior art]
When a moving image is included in the video signal, the luminance of the video signal is lowered and a blurred outline is likely to occur. Therefore, in order to display a moving image clearly and beautifully, a display device having a video signal correction circuit for correcting the brightness and contour of the screen has been devised.
[0003]
As an example of such a video signal correction circuit, for example, there is a technique described in JP-A-1-215185. FIG. 19 shows a block diagram of this technique, in which a video signal input terminal 1, a correction amount determination circuit 4, a contour correction circuit 6, a video signal output terminal 7 and a motion detection circuit 10 are shown.
[0004]
The operation of this technique will be described below. First, the video signal S1 is given to the video signal input terminal 1 and inputted to the motion detection circuit 10 and the contour correction circuit 6, respectively. The motion detection circuit 10 detects a motion vector of a moving image portion in the input video signal S1. The motion vector is detected for each block obtained by dividing the screen into a plurality of parts. The correction amount determination circuit 4 determines the contour correction amount based on the motion vector information S10 for each block output from the motion detection circuit 10, and outputs the information to the contour correction circuit 6 as information S4. Then, the contour correction circuit 6 emphasizes the contour for the moving image portion of the video signal S1 based on the contour correction amount information S4 and does not perform the contour correction for the still image portion, and converts the video signal S6 into the video signal. Output to the output terminal 7.
[0005]
[Problems to be solved by the invention]
However, in the configuration like the technique described in the above publication, the motion detection circuit 10 is necessary to detect the moving image portion of the video signal. Since the motion detection circuit has a complicated circuit configuration and is expensive, it becomes a bottleneck in realizing cost reduction.
[0006]
The present invention has been made to solve the above-described problem, and easily detects a moving image range of a video signal without using a motion detection circuit, and corrects the video signal for the moving image. Thus, a video signal correction circuit capable of outputting a high-resolution video signal and outputting a video signal with a small amount of shoot without correcting a still image is realized.
[0007]
[Means for Solving the Problems]
  According to a first aspect of the present invention, there is provided a detecting means for detecting the detection signal from a video signal including a first portion to which a detection signal is added and a second portion to which the detection signal is not added. Correction means for correcting at least one of luminance and contour of either the portion of the video signal where the detection signal is detected by the detection means or the portion where the detection signal is not detected.The first portion corresponds to a moving image, the second portion corresponds to a still image, and the detection signal has a pedestal level of a portion in the video period of the video signal by a predetermined magnitude. A set-up signal to be raised, wherein the detection means calculates a length of a period in which the value of the video signal takes a value larger than a predetermined value in a horizontal synchronization period, and the horizontal synchronization of the length of the period It is a video signal correction circuit that also calculates a ratio with respect to a period and determines whether the detection signal is present in the horizontal synchronization period based on the ratio.
[0008]
  The invention according to claim 2 is as follows.Detection means for detecting the detection signal from a video signal including a first part to which a detection signal is added and a second part to which the detection signal is not added, and the detection signal by the detection means among the video signals Correction means for correcting at least one of luminance and contour of either the portion where the detection signal is not detected or the portion where the detection signal is not detected, and the first portion corresponds to a moving image, The second part corresponds to a still image, and the detection signal is defined by a pulsed negative signal having the same polarity as the horizontal synchronization signal of the video signal and distinguishable from the horizontal synchronization signal. The detecting means calculates a length of a period in which the value of the video signal is smaller than a predetermined value in a horizontal synchronization period, and whether the negative signal is present based on the length of the period Judge whether And, the determining whether the detection signal in the horizontal synchronizing period there is a video signal correction circuit.
[0009]
  According to claim 3 of the present invention,Detection means for detecting the detection signal from a video signal including a first part to which a detection signal is added and a second part to which the detection signal is not added, and the detection signal by the detection means among the video signals Correction means for correcting at least one of luminance and contour of either the portion where the detection signal is detected or the portion where the detection signal is not detected, and the first portion corresponds to the in-frame image. The second portion corresponds to a background image, and the detection signal is a pulse-like negative signal having the same polarity as the horizontal synchronizing signal of the video signal and distinguishable from the horizontal synchronizing signal. The detection means calculates a length of a period in which the value of the video signal takes a value smaller than a predetermined value in a horizontal synchronization period, and the negative signal is present based on the length of the period. Determine whether It is, determines whether the detection signal in the horizontal synchronizing period there is the video signal correction circuit.
[0010]
  The invention according to claim 4 is the invention according to claim 2.Or claim 3The video signal correction circuit according to claim 1,The negative signal has an absolute value smaller than an absolute value of the horizontal synchronization signal, a pulse width larger than a pulse width of the horizontal synchronization signal, and a portion other than the video period in the horizontal synchronization period. The detection means determines that the detection signal is present throughout the horizontal synchronization period in which the negative signal exists.
[0011]
  The invention according to claim 5 is the video signal correction circuit according to claim 2 or 3, whereinThe negative signal has an absolute value smaller than the absolute value of the horizontal synchronization signal, and its pulse width is larger than the pulse width of the horizontal synchronization signal, and is provided in a pair in the horizontal synchronization period, One of the pair defines the start of the detection signal, the other of the pair defines the end of the detection signal, and the detection means determines that the detection signal is present throughout a period between the pair of the negative signals. .
[0012]
  The invention according to claim 6 is the claim.1 to 5The video signal correction circuit according to claim 1,The detection signal is added to all the video signals in one image frame.
[0013]
  According to claim 7 of the present invention,Detection means for detecting the detection signal from a video signal including a first part to which a detection signal is added and a second part to which the detection signal is not added, and the detection signal by the detection means among the video signals Correction means for correcting at least one of luminance and contour of either the part where the detection signal is detected or the part where the detection signal is not detected, and the detection means includes a horizontal synchronization frequency of the video signal Is a video signal correction circuit that changes the correction amount in the correction means and increases the correction amount as the horizontal synchronization frequency value is lower..
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
In this embodiment, a detection signal for detecting a moving image is added to a video signal in advance to distinguish a moving image from a still image without using a motion detection circuit. A circuit for correcting the luminance and the contour only in the signal portion is realized.
[0017]
A setup signal is used as a detection signal for moving image detection in the present embodiment. The setup signal here means that, in order to improve the contrast reduction in the intermediate luminance range caused by the luminance characteristics (gamma characteristic, etc.) of the CRT, conventionally, the CRT video signal is uniformly applied to the entire video period. It means a correction signal that has been added as a constant bias that raises the destal level.
[0018]
In the present embodiment, the setup signal is not added uniformly throughout the entire video period as in the prior art, but is added only during the video period tv in the screen frame including the moving image as shown in FIG. A distinction is made between moving images and still images in units of screen frames. FIG. 1 shows the video signal Sv1 to which the setup signal Ss is added and the video signal Sv2 to which the setup signal Ss is not added together with the horizontal and vertical synchronization signals. Referring to FIG. 1, it can be seen that the signal intensity of the video signal Sv1 is increased by a certain bias by adding the setup signal Ss during the video period tv. On the other hand, since the setup signal Ss is not added to the video signal Sv2, the signal strength remains unchanged.
[0019]
It is assumed that such a setup signal Ss is added only to the moving image portion in advance on the video software producer side in cooperation with the video software producer.
[0020]
FIG. 2 shows a video signal correction circuit CT1 that corrects a portion of the video signal to which a setup signal is added. The video signal correction circuit CT1 temporarily receives the video signal input terminal 1, the setup signal detection circuit 2 that receives the video signal S1 input to the video signal input terminal 1 and outputs setup signal information S2, and the video signal S1. The frame buffer 3 that stores and outputs as the video signal S3, the discrimination / correction amount determination circuit 4 that receives the setup signal information S2 and outputs the discrimination / correction amount information S4, and the video signal S3 that receives the discrimination / correction amount information S4 Is subjected to luminance correction, and the luminance correction circuit 5 for outputting the luminance-corrected video signal S5 is received, and the luminance-corrected video signal S5 is subjected to contour correction in response to the discrimination / correction amount information S4, and the luminance / contour-corrected video signal S6. Is provided, and a video signal output terminal 7 is provided.
[0021]
3 to 8 individually show configuration examples of the setup signal detection circuit 2, the discrimination / correction amount determination circuit 4, the luminance correction circuit 5, and the contour correction circuit 6 or their operation characteristics.
[0022]
As shown in FIG. 3, the setup signal detection circuit 2 receives the video signal S1, clamps its pedestal level, and outputs the clamp signal S1a as a clamp signal S1a, and a certain value (an example in the present embodiment). And a comparator CP that outputs a comparison result as setup signal information S2 in comparison with 2.03 [V]).
[0023]
Further, as shown in FIG. 4, the discrimination / correction amount determination circuit 4 receives the setup signal information S2, determines the presence / absence of the setup signal, determines the correction amount, and outputs the discrimination / correction amount information S4. It is composed of Note that a clock and a horizontal synchronizing signal of the video signal S1 are also input to the microprocessor MP1.
[0024]
Further, as shown in FIG. 5, the luminance correction circuit 5 includes a multiplier MU that outputs a result obtained by multiplying the luminance compensation characteristic information SC by a voltage amplification degree A that is a constant value as an amplification characteristic signal S7, and discrimination / correction amount information S4. And an amplifier AP that receives the amplification characteristic signal S7, amplifies the luminance of the video signal S3, and outputs it as a luminance-corrected video signal S5. Note that the luminance compensation characteristic information SC is not a characteristic as shown in (1) of FIG. 6 in which a voltage proportional to the intensity of the input video signal is output, and is output as the intensity of the input video signal takes an intermediate value. The characteristic is as shown in (2) of FIG.
[0025]
Further, as shown in FIG. 7, the contour correction circuit 6 has a transistor for amplifying the AC component of the input signal therein, and emphasizes the contour of the luminance corrected video signal S5 as shown in FIG. The luminance / contour corrected video signal S6 is output. Note that a current source is connected to the transistor, and by controlling the current value of the current source based on the discrimination / correction amount information S4, the correction amount can be changed or no contour correction can be performed.
[0026]
Next, the operation of the video signal correction circuit CT1 will be described below with reference to FIGS.
[0027]
First, consider the case where the video signal S1 input to the video input terminal 1 has a setup signal. As shown in FIG. 9, the video signal S1 has a pedestal level of 0 [V], a horizontal synchronization signal in a direction lower than the pedestal level, and a horizontal synchronization period (from one horizontal synchronization signal to the next horizontal synchronization signal. A video signal Sv1 to which a set-up signal Ss having a constant bias value (0.05 [V] as an example in FIG. 9) is added in a direction higher than the pedestal level in a video period tv within th. ing. Here, as an example, the upper limit value of the intensity of the video signal S1 is about 0.7 [V].
[0028]
The video signal Sv1 is input to the setup signal detection circuit 2, clamped by, for example, +2 [V] by the clamp circuit CL, and output as the clamp signal S1a. The comparator CP is larger than the clamp level (2 [V] described above), and the sum of the clamp level and the bias value of the setup signal (2 [V] +0.05 [V] = 2.05 [V]). ) Is compared with the clamp signal S1a, and when the clamp signal S1a is larger, for example, the setup signal information S2 is output as active. In this embodiment, Hi active is adopted as an example, and in FIG. 9, the active period is displayed as the detection period td1. The reason for clamping is that stable comparison can be performed by using a clamped value rather than performing comparison near 0 [V].
[0029]
The setup signal information S2 is input to the Low → Hi interrupt detection unit INT1 and the Hi → Low interrupt detection unit INT2 of the microprocessor MP1 constituting the determination / correction amount determination circuit 4, and the active period and the inactive period are determined by the microprocessor MP1. Calculated by This calculation is performed, for example, by operating a timer in the microprocessor MP1. First, if the rising edge of the setup signal information S2 is detected by the Low → Hi interrupt detection unit INT1, the timer is activated. Next, if the falling edge of the setup signal information S2 is detected by the Hi → Low interrupt detection unit INT2, the timer is stopped and the period of Hi is calculated. At this time, the timer is reset and restarted. Next, when the rising edge of the setup signal information S2 is detected by the Low → Hi interrupt detection unit INT1, the timer is stopped again, and the Low period is calculated.
[0030]
Using the Hi period and the Low period obtained in this way, the microprocessor MP1 calculates the ratio of the Hi period to the total value of the Hi period and the Low period. This ratio corresponds to the ratio of the detection period td1 to the horizontal synchronization period th in FIG. When the video signal S1 has a setup signal, the detection period td1 in FIG. 9 coincides with the video period tv, so the value of the ratio of the detection period td1 to the horizontal synchronization period th is the video for the horizontal synchronization period th. It corresponds to the value of the ratio of the period tv.
[0031]
On the other hand, when the video signal S1 input to the video input terminal 1 does not have a setup signal, the following occurs.
[0032]
As shown in FIG. 10, the video signal Sv2 does not include the setup signal Ss. This video signal Sv2 is also input to the setup signal detection circuit 2, clamped by, for example, +2 [V] by the clamp circuit CL, and output as the clamp signal S1a. Then, as in the previous case, the comparator CP compares the above-mentioned 2.03 [V] with the clamp signal S1a, and outputs the setup signal information S2 as active when the clamp signal S1a is larger.
[0033]
As in the previous case, the setup signal information S2 is input to the Low → Hi interrupt detection unit INT1 and Hi → Low interrupt detection unit INT2 of the microprocessor MP1 constituting the determination / correction amount determination circuit 4, and the active period and The inactive period is calculated by the microprocessor MP1.
[0034]
In the case of FIG. 10, since the clamp signal S1a in the video period tv has a portion below 2.03 [V], the detection periods td2 and td3 of the setup signal information S2 are equal to the detection period td1 in the previous case. Thus, it does not coincide with the whole period of the video period tv. Further, the ratio of the Hi period to the total value of the Hi period and the Low period corresponds to the ratio of the sum of the detection period td2 and the detection period td3 to the horizontal synchronization period th in FIG. 10, and the value of the ratio is the setup signal. Is smaller than the value of the ratio of the detection period td1 to the horizontal synchronization period th.
[0035]
Therefore, the microprocessor MP1 determines whether there is a detection signal in the horizontal synchronization period th based on the ratio of the detection period to the horizontal synchronization period th. Specifically, the value of the ratio of the video period tv to the horizontal synchronization period th is stored in advance in the memory or register of the microprocessor MP1 as a threshold value, and the setup signal information S2 for the horizontal synchronization period th of the video signal S1 is stored. When the ratio value of the detection period is equal to or greater than the threshold value, the microprocessor MP1 determines that the setup signal is present in the horizontal synchronization period, and outputs the discrimination / correction amount information S4 as active. Otherwise, it is determined that there is no set-up signal during the horizontal synchronization period, and the discrimination / correction amount information S4 is output as inactive. In this way, it is possible to determine whether a setup signal is included for each horizontal synchronization period of the video signal S1.
[0036]
A plurality of active levels may be provided, and the signal intensity of the discrimination / correction amount information S4 may be changed according to the frequency characteristics of the video signal S1. Among video signals, increasing the horizontal synchronization frequency while keeping the vertical synchronization frequency constant will increase the number of scans on the display screen. As a result, the accuracy of the display screen increases and the need for correction is reduced. Because. If the correction amount is too large despite the high accuracy of the display screen, the quality of the image may be deteriorated. Therefore, if the value of the horizontal synchronization frequency is high, the correction amount may be reduced. That is, the signal intensity of the discrimination / correction amount information S4 may be changed so that the correction amount increases as the horizontal synchronization frequency value decreases. For example, when it is determined that there is no setup signal, the signal strength of the discrimination / correction amount information S4 is 0 [V], and when the setup signal is determined to be present, the horizontal synchronization frequency of the video signal is, for example, 30 [V]. In the case of [kHz], the signal intensity of the discrimination / correction amount information S4 is 5 [V], and it is judged that the setup signal is present and the horizontal synchronization frequency of the video signal is 60 [kHz], for example. When the signal strength of the correction amount information S4 is 3 [V] and the setup signal is determined to be present and the horizontal synchronization frequency of the video signal is, for example, 90 [kHz], the signal of the determination / correction amount information S4 The intensity may be set so as to be 2 [V]. In this way, when the value of the horizontal synchronization frequency is high, the correction amount is increased too much and the quality of the image is not deteriorated.
[0037]
When the luminance correction circuit 5 receives the discrimination / correction amount information S4, the frame buffer 3 is controlled so that the video signal in the corresponding horizontal synchronization period is given as the video signal S3. The amplifier AP amplifies the video signal in the horizontal synchronization period in which the microprocessor MP1 has activated the discrimination / correction amount information S4 using the amplification characteristic signal S7 output from the multiplier MU. The video signal S3 is amplified with the proportional characteristic as shown in (1) of FIG. 6 without using the amplification characteristic signal S7 for the video signal in the horizontal synchronization period in which the MP1 has made the discrimination / correction amount information S4 inactive. Each of them is output as a luminance corrected video signal S5. In addition, when there are a plurality of stages in the signal intensity of the discrimination / correction amount information S4, the amplification degree in the amplifier AP may be changed. That is, the lower the horizontal synchronization frequency value, the higher the amplification degree may be.
[0038]
Similarly, the contour correction circuit 6 controls the luminance correction circuit 5 so that the video signal in the corresponding horizontal synchronization period is given as the luminance corrected video signal S5 when the discrimination / correction amount information S4 is received. The contour correction circuit 6 emphasizes the contour of the video signal in the horizontal synchronization period in which the microprocessor MP1 has activated the discrimination / correction amount information S4, and the microprocessor MP1 uses the discrimination / correction amount information S4. The inactive video signal in the horizontal synchronization period is output as a luminance / contour corrected video signal S6 without enhancing the contour. In addition, when there are a plurality of levels in the signal intensity of the discrimination / correction amount information S4, the contour enhancement amount may be changed. That is, it is only necessary that the amount of contour enhancement increases as the horizontal synchronization frequency value decreases.
[0039]
In the above description, the luminance correction circuit 5 and the contour correction circuit 6 correct the video signal in the horizontal synchronization period in which the discrimination / correction amount information S4 is active. However, the discrimination / correction amount information S4 is reversed. It is also possible to correct the video signal in the inactive horizontal synchronization period. In this case, since the still image is corrected instead of the moving image, for example, the contour correction circuit 6 does not emphasize the contour, but conversely corrects the contour by making it ambiguous. A method of emphasizing the contour of a moving image more than the contour of a still image is conceivable.
[0040]
Note that either one of the luminance correction circuit 5 and the contour correction circuit 6 may be omitted. When the luminance correction circuit 5 is omitted, the video signal S3 output from the frame buffer 3 is directly input to the contour correction circuit 6, and when the contour correction circuit 6 is omitted, the output of the luminance correction circuit 5 is output. The luminance corrected video signal S5 is only output from the video signal output terminal 7.
[0041]
By using the video signal correction circuit according to the present embodiment, it is possible to easily distinguish between a still image portion and a moving image portion of a video signal without using a motion detection circuit. Either one of the luminance and the contour can be corrected.
[0042]
In the above description, the setup signal is added in units of screen frames. However, in principle, the setup signal is added every horizontal synchronization period, so correction may be performed every horizontal synchronization period. Is possible. However, in this case, correction may be performed for each scanning line, or it may be difficult to see. If a setup signal is added in units of screen frames, there is little possibility that the screen will be difficult to see. This is because, in general, only one of moving images and still images is displayed for a certain period over a plurality of consecutive frames, and it is considered that the frequency with or without correction is low. .
[0043]
By the way, when this embodiment is used, if a high level continues throughout the video period even though no setup signal is added, it is determined and corrected that the setup signal was added during the horizontal synchronization period. The quantity determination circuit 4 will misidentify. However, compared to the effect of miscorrecting a moving image as a still image and not correcting it, the effect of correcting a still image as a moving image is not considered to be significant. There is no means for correction.
[0044]
Embodiment 2. FIG.
In the present embodiment, similarly to the first embodiment, by adding a detection signal for moving image detection to the video signal in advance, a moving image and a still image are distinguished without using a motion detection circuit. A circuit that corrects only the video signal portion to which the detection signal is added is realized.
[0045]
The detection signal for moving image detection in the present embodiment can be distinguished from the horizontal synchronization signal, but is generated in a direction lower than the pedestal level similar to the horizontal synchronization signal (having the same polarity as the horizontal synchronization signal). ) It is defined by a pulse signal. In the present application, this signal is referred to as a negative signal.
[0046]
In this embodiment, as shown in FIG. 11, a pair of negative signals is added before and after the video period tv in a screen frame including a moving image, and a moving image and a still image are distinguished on a screen frame basis. FIG. 11 shows the video signal Sv3 to which the negative signals Sn1 and Sn2 are added and the video signal Sv4 to which the negative signal is not added together with the horizontal and vertical synchronizing signals. Here, a pair of one negative signal defines the start end of the detection signal, and the other negative signal defines the end of the detection signal, and the video signal portion between both negative signals is corrected.
[0047]
It is assumed that such negative signals Sn1 and Sn2 are added only to the moving image portion in advance on the video software producer side in cooperation with the video software producer as in the first embodiment.
[0048]
FIG. 12 shows a video signal correction circuit CT2 that corrects a video signal portion between both negative signals in the video signal. The video signal correction circuit CT2 temporarily receives the video signal input terminal 1, the negative signal detection circuit 8 that receives the video signal S1 input to the video signal input terminal 1 and outputs negative signal information S8, and the video signal S1. The frame buffer 3 that stores and outputs as the video signal S3, the discrimination / correction amount determination circuit 9 that receives the negative signal information S8 and outputs the discrimination / correction amount information S9, and the video signal S3 that receives the discrimination / correction amount information S9 Is subjected to luminance correction, and the luminance correction circuit 5 for outputting the luminance corrected video signal S5, and the luminance correction / contour corrected video signal S6 in response to the discrimination / correction amount information S9 and the luminance correction video signal S5 are subjected to contour correction. Is provided, and a video signal output terminal 7 is provided.
[0049]
FIG. 13 shows a configuration example of the negative signal detection circuit 8, and FIG. 14 shows a configuration example of the discrimination / correction amount determination circuit 9.
[0050]
As shown in FIG. 13, the negative signal detection circuit 8 includes a capacitor CA that cuts a DC component from the video signal S1, clamps the pedestal level of the video signal S1 from which the DC component has been cut, and outputs the clamped signal S1b. And a comparator CP that compares the clamp signal S1b with a certain value (in this embodiment, 1.95 [V] as an example) and outputs the comparison result as negative signal information S8.
[0051]
Further, as shown in FIG. 14, the discrimination / correction amount determination circuit 9 receives the negative signal information S8, determines the presence / absence of the negative signal, determines the correction amount, and outputs the discrimination / correction amount information S9. It is composed of Note that a clock and a horizontal synchronizing signal of the video signal S1 are also input to the microprocessor MP2.
[0052]
The brightness correction circuit 5 is the same as that shown in FIG. 5 except that the discrimination / correction amount information S4 in FIG. 5 is changed to discrimination / correction amount information S9.
[0053]
The contour correction circuit 6 is also the same as that of FIG. 7 except that the discrimination / correction amount information S4 in FIG. 7 is changed to discrimination / correction amount information S9.
[0054]
Next, the operation of the video signal correction circuit CT2 will be described below with reference to FIGS.
[0055]
First, consider a case where the video signal S1 input to the video input terminal 1 has a negative signal. As shown in FIG. 15, the video signal S1 includes a horizontal synchronization signal and negative signals Sn1 and Sn2 in a direction lower than the pedestal level with a pedestal level of 0 [V], and a video signal Sv3 in the video period tv. ing. Since the horizontal synchronization signal and the negative signals Sn1 and Sn2 need to be distinguished, the absolute values of the negative signals Sn1 and Sn2 are set smaller than the absolute value of the horizontal synchronization signal. Here, as an example, the value of the horizontal synchronizing signal is set to -0.3 [V], and the values of the negative signals Sn1 and Sn2 are set to -0.1 [V]. Further, the pulse width tn of the negative signals Sn1, Sn2 is made larger than the pulse width ts of the horizontal synchronizing signal so that the two can be distinguished from each other.
[0056]
The video signal Sv3 is input to the negative signal detection circuit 8, and after the DC component is cut, it is clamped, for example, by +2 [V] by the clamp circuit CL, and is output as the clamp signal S1b. The comparator CP is smaller than the clamp level (2 [V] described above), and is obtained by subtracting the absolute value of the negative signal from the clamp level (2 [V] −0.1 [V] = 1.9 [ V]) is compared with the clamp signal S1b, and when the clamp signal S1b is larger, for example, the negative signal information S8 is output as active. In this embodiment, Hi active is adopted as an example.
[0057]
The negative signal information S8 is input to the Low → Hi interrupt detection unit INT1 and the Hi → Low interrupt detection unit INT2 of the microprocessor MP2 constituting the determination / correction amount determination circuit 9, and the inactive period is the same as in the first embodiment. It is calculated by the microprocessor MP2 in the same way as the microprocessor MP1.
[0058]
The calculated inactive period includes the pulse width ts of the horizontal synchronizing signal and the pulse width tn of the negative signal. The microprocessor MP2 uses the difference in the pulse width to make a negative signal. Only the pulse width tn is extracted. That is, the value of the pulse width tn of the negative signal is stored in advance in a memory or register in the microprocessor MP2, and roughly matches the value of the pulse width tn of the negative signal in the inactive period in the negative signal information S8. If there is something, it is determined that a negative signal exists.
[0059]
On the other hand, when the video signal S1 input to the video input terminal 1 does not have a negative signal, it is clamped by the clamp circuit CL in the same manner as described above, and the inactive period is calculated in the microprocessor MP2. However, since only the horizontal sync signal can be detected, the negative signal is not detected.
[0060]
The microprocessor MP2 determines that there is a detection signal for moving image detection during the period between the two negative signals, and outputs the discrimination / correction amount information S9 as active during that period. Otherwise, it is determined that there is no negative signal during the horizontal synchronization period, and the discrimination / correction amount information S8 is output as inactive. In this way, it is possible to reliably determine whether a detection signal for moving image detection is included for each horizontal synchronization period of the video signal S1. In addition, since the pair of negative signals defines the start and end of the detection signal, the range to be corrected within the horizontal synchronization period can be arbitrarily set (however, in this embodiment, the correction is performed through the video period tv. Will be placed somewhere in the horizontal blanking interval).
[0061]
Incidentally, when detecting the horizontal synchronization signal from the video signal, there may be a concern that a negative signal may be erroneously included. However, it is possible to detect only the horizontal synchronization signal without detecting the negative signals Sn1, Sn2. FIG. 16 shows this, which is smaller than the value obtained by subtracting the absolute value of the negative signal from the clamp level (2 [V] −0.1 [V] = 1.9 [V]). A value larger than the value obtained by subtracting the absolute value of the horizontal synchronizing signal from 2 (V [V] −0.3 [V] = 1.7 [V]) (for example, 1.8 [V] as shown in FIG. 16) May be used as a reference value for comparison with the clamp signal S1b. In this way, only the horizontal synchronization signal can be detected.
[0062]
As in the first embodiment, a plurality of active levels may be provided, and the signal intensity of the discrimination / correction amount information S9 may be changed according to the frequency characteristics of the video signal S1. That is, the signal intensity of the discrimination / correction amount information S9 may be changed so that the correction amount increases as the horizontal synchronization frequency value decreases. In this way, when the value of the horizontal synchronization frequency is high, the correction amount is increased too much and the quality of the image is not deteriorated.
[0063]
When the luminance correction circuit 5 receives the discrimination / correction amount information S9, as in the first embodiment, the frame buffer 3 is controlled so that the video signal in the corresponding horizontal synchronization period is given as the video signal S3. The amplifier AP amplifies the video signal in the horizontal synchronization period in which the microprocessor MP2 has activated the discrimination / correction amount information S9 by using the amplification characteristic signal S7 output from the multiplier MU. The video signal S3 is amplified with the proportional characteristic as shown in (1) of FIG. 6 without using the amplification characteristic signal S7 for the video signal in the horizontal synchronization period in which the MP2 has made the discrimination / correction amount information S9 inactive. Each of them is output as a luminance corrected video signal S5. In addition, when there are a plurality of stages in the signal intensity of the discrimination / correction amount information S8, the degree of amplification in the amplifier AP may be changed. That is, the lower the horizontal synchronization frequency value, the higher the amplification degree may be.
[0064]
Similarly, the contour correction circuit 6 controls the luminance correction circuit 5 so that the video signal in the corresponding horizontal synchronization period is given as the luminance corrected video signal S5 when receiving the discrimination / correction amount information S9. The contour correction circuit 6 emphasizes the contour of the video signal in the horizontal synchronization period in which the microprocessor MP2 activates the discrimination / correction amount information S9, and the microprocessor MP2 displays the discrimination / correction amount information S9. The inactive video signal in the horizontal synchronization period is output as a luminance / contour corrected video signal S6 without enhancing the contour. In addition, when there are a plurality of stages in the signal intensity of the discrimination / correction amount information S9, the contour enhancement amount may be changed. That is, it is only necessary that the amount of contour enhancement increases as the horizontal synchronization frequency value decreases.
[0065]
In the above description, the luminance correction circuit 5 and the contour correction circuit 6 correct the video signal in the horizontal synchronization period in which the discrimination / correction amount information S9 is active. It is also possible to correct the video signal in the inactive horizontal synchronization period.
[0066]
Note that either one of the luminance correction circuit 5 and the contour correction circuit 6 may be omitted. When the luminance correction circuit 5 is omitted, the video signal S3 output from the frame buffer 3 is directly input to the contour correction circuit 6, and when the contour correction circuit 6 is omitted, the output of the luminance correction circuit 5 is output. The luminance corrected video signal S5 is only output from the video signal output terminal 7.
[0067]
By using the video signal correction circuit according to the present embodiment, it is possible to easily distinguish between a still image portion and a moving image portion of a video signal without using a motion detection circuit. Either one of the luminance and the contour can be corrected.
[0068]
Further, since a negative signal having the same polarity as that of the horizontal synchronizing signal is used, unlike the first embodiment, there is a low possibility that a detection signal for detecting a moving image is mistaken and added.
[0069]
In the above description, the negative signal is added in units of screen frames. However, in principle, since the negative signal is added every horizontal synchronization period, correction may be performed every horizontal synchronization period. Is possible.
[0070]
Further, in this embodiment, the negative signals are used as a set of two, but a pair of negative signals is not necessarily required to perform correction through the video period tv of the horizontal synchronization period. That is, if the determination / correction amount determination circuit 9 detects one negative signal at any part of the horizontal synchronization period other than the video period, it is determined that the detection signal is present during the horizontal synchronization period through the video period tv. It may be said that. Therefore, for example, one of the negative signals Sn1 and Sn2 in FIGS. 10 and 15 is omitted, and the operation of the determination / correction amount determination circuit 9 is not as described above, but the luminance correction circuit 5 and the contour correction circuit 6 are one. An operation may be performed in which the discrimination / correction amount information S9 is activated when correction is performed in the horizontal synchronization period in which two detection signals are detected.
[0071]
Embodiment 3 FIG.
The present embodiment is a modification in which an operation other than the correction of a video signal to a moving image is performed using the video signal correction circuit according to the second embodiment.
[0072]
Also in this embodiment, two negative signals are used as one set, and the first negative signal is used as the start of the detection signal and the next negative signal is used as the end of the detection signal to correct the video signal portion between the two negative signals. To do.
[0073]
However, in the second embodiment, the pair of negative signals Sn1 and Sn2 are arranged in the horizontal blanking period, but in the present embodiment, the negative signals Sn1 and Sn2 are arranged in the video period tv. Since the negative signal is lower than the pedestal level, the image is a black signal, but this is used to correct the brightness and contour of the display inside the window on the screen (the window is usually black) Therefore, there is no problem even if a negative signal is superimposed on the contour line portion). Since the negative signals Sn1 and Sn2 define the start and end of the detection signal, the correction range can be arbitrarily set within the video period tv.
[0074]
17 and 18 are diagrams for explaining this. FIG. 17 shows a state where the window WD is displayed on the screen of the display DP. FIG. 18 shows a video signal of one scanning line LN crossing the window WD in the screen of the display DP. The negative signals Sn1 and Sn2 in FIG. 18 correspond to the outline portion of the window WD in FIG. 17, and the portion surrounded by both negative signals corresponds to the image within the frame of the window WD. Further, the horizontal synchronization period th corresponds to the scanning line LN.
[0075]
By using the video signal correction circuit according to the present embodiment, it is possible to distinguish between the image portion in the frame of the window WD and the image portion of the other background, and the image portion or background in the frame of the window WD. It is possible to correct at least one of the brightness and the contour of either one of the image portions.
[0076]
【The invention's effect】
  If the video signal correction circuit according to the first aspect of the present invention is used, the first portion and the second portion of the video signal can be easily distinguished from each other. At least one of the luminance and the contour can be corrected.Furthermore, it is possible to easily distinguish the moving image portion and the still image portion of the video signal without using a motion detection circuit, and at least one of the luminance and the contour of either the moving image portion or the still image portion. One can be corrected. Further, it can be determined whether or not a detection signal is included for each horizontal synchronization period of the video signal.
[0077]
  If the video signal correction circuit according to claim 2 of the present invention is used,The first portion and the second portion of the video signal can be easily distinguished, and at least one of the luminance and the contour of either the first or second portion can be corrected. . Furthermore, it is possible to easily distinguish the moving image portion and the still image portion of the video signal without using a motion detection circuit, and at least one of the luminance and the contour of either the moving image portion or the still image portion. One can be corrected. Further, it can be determined whether or not a detection signal is included for each horizontal synchronization period of the video signal. Further, since a negative signal having the same polarity as the horizontal synchronization signal is used, it is unlikely that the detection signal is erroneously recognized and added.
[0078]
  If the video signal correction circuit according to claim 3 of the present invention is used,The first portion and the second portion of the video signal can be easily distinguished, and at least one of the luminance and the contour of either the first or second portion can be corrected. . Furthermore, it is possible to distinguish between the frame image portion and the background image portion in the video signal, and it is possible to correct at least one of the luminance and the contour of either the frame image portion or the background image portion. . Further, it can be determined whether or not a detection signal is included for each horizontal synchronization period of the video signal. Further, since a negative signal having the same polarity as the horizontal synchronization signal is used, it is unlikely that the detection signal is erroneously recognized and added.
[0079]
  If the video signal correction circuit according to claim 4 of the present invention is used,It is possible to reliably determine whether a detection signal is included for each horizontal synchronization period of the video signal.
[0080]
  If the video signal correction circuit according to claim 5 of the present invention is used,It is possible to reliably determine whether a detection signal is included for each horizontal synchronization period of the video signal. In addition, since the pair of negative signals defines the start and end of the detection signal, the range to be corrected within the horizontal synchronization period can be arbitrarily set.
[0081]
  If the video signal correction circuit according to claim 6 of the present invention is used,Since the detection signal is added not in units of horizontal synchronization periods but in units of screen frames, there is little possibility that the screen will be difficult to see.
[0082]
  If the video signal correction circuit according to claim 7 of the present invention is used,The first portion and the second portion of the video signal can be easily distinguished, and at least one of the luminance and the contour of either the first or second portion can be corrected. . If the video signal correction circuit according to the ninth aspect of the present invention is used, when the value of the horizontal synchronization frequency is high, the correction amount is excessively increased and the quality of the image is not degraded.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an example of a video signal supplied to a video signal correction circuit according to a first embodiment.
FIG. 2 is a diagram illustrating a video signal correction circuit according to the first embodiment.
FIG. 3 is a diagram illustrating a setup signal detection circuit in the video signal correction circuit according to the first embodiment.
4 is a diagram showing a discrimination / correction amount determination circuit in the video signal correction circuit according to the first embodiment; FIG.
5 is a diagram showing a luminance correction circuit in the video signal correction circuit according to the first embodiment. FIG.
6 is a diagram illustrating luminance compensation characteristics of a luminance correction circuit in the video signal correction circuit according to the first embodiment. FIG.
7 is a diagram showing a contour correction circuit in the video signal correction circuit according to the first embodiment; FIG.
FIG. 8 is a diagram illustrating an operation example of a contour correction circuit in the video signal correction circuit according to the first embodiment;
FIG. 9 is a diagram illustrating an operation example of the video signal correction circuit according to the first embodiment;
10 is a diagram illustrating an operation example of the video signal correction circuit according to the first embodiment; FIG.
FIG. 11 is a diagram illustrating an example of a video signal supplied to the video signal correction circuit according to the second embodiment.
12 is a diagram illustrating a video signal correction circuit according to a second embodiment. FIG.
FIG. 13 is a diagram illustrating a negative signal detection circuit in the video signal correction circuit according to the second embodiment.
FIG. 14 is a diagram showing a discrimination / correction amount determination circuit in the video signal correction circuit according to the second embodiment;
FIG. 15 is a diagram illustrating an operation example of the video signal correction circuit according to the second embodiment;
FIG. 16 is a diagram illustrating an operation example of the video signal correction circuit according to the second embodiment;
FIG. 17 is a diagram illustrating an example of a display screen in which the video signal correction circuit according to the third embodiment is effective.
FIG. 18 is a diagram illustrating an example of a video signal supplied to the video signal correction circuit according to the third embodiment.
FIG. 19 is a diagram illustrating a conventional video signal correction circuit.
[Explanation of symbols]
2 Setup signal detection circuit, 4, 9 Discrimination / correction amount determination circuit, 5 Brightness correction circuit, 6 Contour correction circuit, 8 Negative signal detection circuit.

Claims (7)

Detecting means for detecting the detection signal from a video signal including a first portion to which a detection signal is added and a second portion to which the detection signal is not added;
A correction unit that corrects at least one of luminance and contour of either one of the portion of the video signal where the detection signal is detected by the detection unit or the portion where the detection signal is not detected ,
The first part corresponds to a moving image, the second part corresponds to a still image,
The detection signal is a setup signal that increases a pedestal level of a portion in the video period of the video signal by a predetermined magnitude,
The detecting means calculates a length of a period in which the value of the video signal takes a value larger than a predetermined value in a horizontal synchronization period, and also calculates a ratio of the length of the period to the horizontal synchronization period. Determining whether the detection signal is in the horizontal synchronization period based on the ratio,
Video signal correction circuit. Detecting means for detecting the detection signal from a video signal including a first portion to which a detection signal is added and a second portion to which the detection signal is not added;
  A correction unit that corrects at least one of luminance and contour of either one of the portion of the video signal where the detection signal is detected by the detection unit or the portion where the detection signal is not detected,
The first part corresponds to a moving image, the second part corresponds to a still image,
The detection signal is defined by a pulsed negative signal having the same polarity as the horizontal synchronization signal of the video signal and distinguishable from the horizontal synchronization signal,
  The detecting means calculates a length of a period in which the value of the video signal takes a value smaller than a predetermined value in a horizontal synchronization period, and determines whether the negative signal is present based on the length of the period. By determining whether the detection signal is present within the horizontal synchronization period;
Video signal correction circuit. Detecting means for detecting the detection signal from a video signal including a first portion to which a detection signal is added and a second portion to which the detection signal is not added;
A correction unit that corrects at least one of luminance and contour of either one of the portion of the video signal where the detection signal is detected by the detection unit or the portion where the detection signal is not detected,
The first part corresponds to an in-frame image, the second part corresponds to a background image,
The detection signal is defined by a pulsed negative signal having the same polarity as the horizontal synchronization signal of the video signal and distinguishable from the horizontal synchronization signal,
The detecting means calculates a length of a period in which the value of the video signal takes a value smaller than a predetermined value in a horizontal synchronization period, and determines whether the negative signal is present based on the length of the period. By determining whether the detection signal is present within the horizontal synchronization period;
Video signal correction circuit . The negative signal has an absolute value smaller than an absolute value of the horizontal synchronization signal, a pulse width larger than a pulse width of the horizontal synchronization signal, and a portion other than the video period in the horizontal synchronization period. Provided in
  The detection means determines that the detection signal is present throughout the horizontal synchronization period in which the negative signal exists.
The video signal correction circuit according to claim 2 or 3. The negative signal has an absolute value smaller than the absolute value of the horizontal synchronization signal, and its pulse width is larger than the pulse width of the horizontal synchronization signal, and a pair is provided in the horizontal synchronization period,
  One of the pair defines the start of the detection signal, and the other of the pair defines the end of the detection signal,
  The detection means determines that the detection signal is present through a period between the pair of negative signals.
The video signal correction circuit according to claim 2 or 3. 6. The video signal correction circuit according to claim 1, wherein the detection signal is added to all the video signals in one image frame. Detecting means for detecting the detection signal from a video signal including a first portion to which a detection signal is added and a second portion to which the detection signal is not added;
A correction unit that corrects at least one of luminance and contour of either one of the portion of the video signal where the detection signal is detected by the detection unit or the portion where the detection signal is not detected,
The detection means changes a correction amount in the correction means according to a horizontal synchronization frequency of the video signal,
The lower the horizontal sync frequency value, the greater the correction amount.
Video signal correction circuit .

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