JP2012220941A - Image processing device and image processing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image processing device capable of achieving higher image quality and an image processing method.SOLUTION: The image processing device related to one embodiment is an image processing device processing an image displayed on a liquid crystal panel in which a plurality of pixels are arranged like a matrix and includes a temperature sensor detecting the temperature of the liquid crystal panel, a receiving part receiving a video signal, a voltage value table outputting a voltage corresponding to a combination of gradations of frames before and after in which the video signals received by the receiving part are continuous, a gain table outputting a gain corresponding to the combination of gradations of the frames before and after and the temperature detected by the temperature sensor, and an overdrive output part performing overdrive based on the voltage outputted from the voltage value table and the gain outputted from the gain table and outputting an overdriven voltage to the liquid crystal panel.

Description

  Embodiments described herein relate generally to an image processing apparatus and an image processing method.

  In recent years, liquid crystal display devices capable of displaying various images have become widespread. The liquid crystal display device includes a liquid crystal display panel including a plurality of pixels arranged in a matrix, and a backlight that illuminates the liquid crystal panel. The liquid crystal display device can control the gradation (luminance) of each pixel by applying a voltage to each pixel of the liquid crystal display panel.

  The liquid crystal display device can continuously change the gradation (luminance) of each pixel by controlling the voltage applied to the pixel for each screen (frame) to be displayed. However, depending on the response speed of the liquid crystal molecules, the change of the screen of the liquid crystal panel may be slow. For this reason, the viewer may recognize it as an afterimage. Therefore, in order to change the target brightness (gradation) more quickly, an overdrive that temporarily applies a voltage higher or lower than the voltage value corresponding to the brightness (gradation) to the pixel has been put into practical use.

  In addition, the response characteristics of the liquid crystal molecules change depending on the temperature. For this reason, there is a technique for switching the degree of overdrive depending on the temperature.

JP 2008-158472 A JP 2007-148369 A

  The relationship between the response characteristics of liquid crystal molecules and temperature also changes depending on the luminance (gradation) of the previous and subsequent frames. That is, when changing a pixel from low luminance (gradation) to high luminance (gradation), and from moderate luminance (gradation) to medium luminance (gradation) different from this luminance (gradation). The relationship between the response characteristics of liquid crystal molecules and temperature differs depending on the change. For this reason, according to the prior art, appropriate control cannot be performed depending on the temperature of the liquid crystal, and there is a problem that flickering and an afterimage may occur on the screen.

  Therefore, an object is to provide an image processing apparatus and an image processing method capable of realizing higher image quality.

  An image processing apparatus according to an embodiment is an image processing apparatus that processes an image displayed on a liquid crystal panel in which a plurality of pixels are arranged in a matrix, a temperature sensor that detects a temperature of the liquid crystal panel, and a video signal A voltage value table that outputs a voltage corresponding to a combination of gradations of consecutive previous and subsequent frames of the video signal received by the receiving unit, and levels of the previous and subsequent frames. A gain table that outputs a gain according to the combination of keys, the temperature detected by the temperature sensor, the voltage output from the voltage value table, and the gain output from the gain table. An overdrive output unit that performs overdrive and outputs the overdriven voltage to the liquid crystal panel. That.

FIG. 1 is a diagram for explaining an image processing apparatus according to an embodiment. FIG. 2 is a diagram for explaining an overdrive processing unit according to an embodiment. FIG. 3 is a diagram for explaining an overdrive processing unit according to an embodiment. FIG. 4 is a diagram for explaining an overdrive processing unit according to an embodiment. FIG. 5 is a diagram for explaining an overdrive processing unit according to an embodiment. FIG. 6 is a diagram for explaining an overdrive processing unit according to an embodiment. FIG. 7 is a diagram for explaining an overdrive processing unit according to an embodiment.

  Hereinafter, an image processing apparatus and an image processing method according to an embodiment will be described in detail with reference to the drawings.

FIG. 1 shows an example of an image processing apparatus 100 according to an embodiment.
In the present embodiment, the image processing apparatus 100 will be described on the assumption that video is displayed on a liquid crystal display device based on content.

  The image processing apparatus 100 includes a broadcast input terminal 101, a tuner 111, a demodulation unit 112, a signal processing unit 113, a communication interface 114, an audio processing unit 121, an audio output terminal 122, a video processing unit 131, an OSD processing unit 132, and a display processing unit. 133, a video output terminal 135, a control unit 150, an operation input unit 161, a light receiving unit 162, a card connector 164, a USB connector 166, and a disk drive 170.

  The broadcast input terminal 101 is an input terminal to which a digital broadcast signal received by the antenna 110 is input, for example. The antenna 110 receives, for example, a terrestrial digital broadcast signal, a BS (broadcasting satellite) digital broadcast signal, and / or a 110-degree CS (communication satellite) digital broadcast signal. That is, content such as a program supplied by a broadcast signal is input to the broadcast input terminal 101.

  The broadcast input terminal 101 supplies the received digital broadcast signal to the tuner 111. The tuner 111 is a tuner for digital broadcast signals. The tuner 111 tunes (tunes) the digital broadcast signal supplied from the antenna 110. The tuner 111 transmits the tuned digital broadcast signal to the demodulation unit 112.

  The demodulator 112 demodulates the received digital broadcast signal. The demodulator 112 inputs the demodulated digital broadcast signal (content) to the signal processor 113. That is, the antenna 110, the tuner 111, and the demodulation unit 112 function as a receiving unit that receives content.

  The signal processing unit 113 functions as a signal processing unit that performs signal processing on a digital broadcast signal (moving content data). The signal processing unit 113 performs signal processing on the digital broadcast signal supplied from the demodulation unit 112. That is, the signal processing unit 113 separates the digital broadcast signal into a video signal, an audio signal, and other data signals. The signal processing unit 113 supplies an audio signal to the audio processing unit 121. Further, the signal processing unit 113 supplies a video signal to the video processing unit 131. Further, the signal processing unit 113 supplies a data signal to the control unit 150 and / or the OSD processing unit 132.

  The communication interface 114 includes an interface capable of receiving content, such as a high definition multimedia interface (HDMI) (registered trademark) terminal. The communication interface 114 receives content in which a digital video signal, a digital audio signal, and the like are multiplexed from another device. The communication interface 114 supplies a digital signal (content) received from another device to the signal processing unit 113. That is, the communication interface 114 functions as a receiving unit that receives content.

  The signal processing unit 113 performs signal processing on the digital signal received from the communication interface 114. For example, the signal processing unit 113 separates the digital signal into a digital video signal, a digital audio signal, and a data signal. The signal processing unit 113 supplies a digital audio signal to the audio processing unit 121. In addition, the signal processing unit 113 supplies a digital video signal to the video processing unit 131. Further, the signal processing unit 113 supplies a data signal to the control unit 150 and / or the OSD processing unit 132.

  Note that the signal processing unit 113 performs processing by selecting either content input to the communication interface 114 or content input to the broadcast input terminal 101. That is, the signal processing unit 113 performs signal separation processing on either the digital broadcast signal or the digital signal.

  The audio processing unit 121 converts the audio signal received from the signal processing unit 113 into an audio signal in a format that can be reproduced by the speaker 200. The audio processing unit 121 outputs an audio signal to the audio output terminal 122. The audio output terminal 122 outputs the supplied audio signal to the outside of the apparatus. Thereby, the speaker 200 connected to the audio output terminal 122 reproduces sound based on the supplied audio signal.

  The video processing unit 131 converts the video signal received from the signal processing unit 113 into a video signal having a format that can be reproduced by the display 300. That is, the video processing unit 131 decodes (reproduces) the video signal received from the signal processing unit 113 into a video signal having a format that can be reproduced by the display 300. In addition, the video processing unit 131 superimposes the OSD signal supplied from the OSD processing unit 132 on the video signal. The video processing unit 131 outputs the video signal to the display processing unit 133.

  The OSD processing unit 132 uses a GUI (graphic user interface) screen, subtitle, time, or other information based on the data signal that is heavily rained from the signal processing unit 113 and / or the control signal supplied from the control unit 150. An OSD signal is generated to superimpose and the like on the screen.

  For example, the display processing unit 133 performs color tone, brightness, sharpness, contrast, or other image quality adjustment processing on the received video signal based on the control from the control unit 150. Further, the display processing unit 133 includes an overdrive processing unit 134. The overdrive processing unit 134 performs overdrive based on continuously input video signals. The display processing unit 133 outputs a video signal subjected to image quality adjustment and overdrive to the video output terminal 135. Accordingly, the display 300 connected to the video output terminal 135 displays a video based on the supplied video signal.

  The display 300 includes, for example, a liquid crystal display device including a liquid crystal display panel including a plurality of pixels arranged in a matrix and a backlight that illuminates the liquid crystal panel. The display 300 displays a video based on the video signal supplied from the image processing apparatus 100.

  Note that the image processing apparatus 100 may be configured to include the display 300 in the apparatus instead of the video output terminal 135. The image processing apparatus 100 may be configured to include the speaker 200 inside the apparatus instead of the audio output terminal 122.

  The control unit 150 functions as a control unit that controls the operation of each unit of the image processing apparatus 100. The control unit 150 includes a CPU 151, a ROM 152, a RAM 153, an EEPROM 154, and the like. The control unit 150 performs various processes based on the operation signal supplied from the operation input unit 161.

  The CPU 151 includes arithmetic elements that execute various arithmetic processes. The CPU 151 implements various functions by executing programs stored in the ROM 152, the EEPROM 154, or the like.

  The ROM 152 stores a program for controlling the image processing apparatus 100, a program for realizing various functions, and the like. The CPU 151 activates the program stored in the ROM 152 based on the operation signal supplied from the operation input unit 161. Thereby, the control part 150 controls operation | movement of each part.

  The RAM 153 functions as a work memory for the CPU 151. That is, the RAM 153 stores the calculation result of the CPU 151, the data read by the CPU 151, and the like.

  The EEPROM 154 is a non-volatile memory that stores various setting information, programs, and the like.

  The operation input unit 161 is an input unit including, for example, an operation key, a keyboard, a mouse, a touch pad, or another input device that can generate an operation signal according to an operation input. For example, the operation input unit 161 generates an operation signal according to the operation input. The operation input unit 161 supplies the generated operation signal to the control unit 150.

  The touch pad includes an electrostatic sensor, a thermo sensor, or a device that generates position information based on other methods. When the image processing apparatus 100 includes the display 300, the operation input unit 161 may include a touch panel formed integrally with the display 300.

  The light receiving unit 162 includes, for example, a sensor that receives an operation signal from the remote controller 163. The light receiving unit 162 supplies the received operation signal to the control unit 150. The remote controller 163 generates an operation signal based on a user operation input. The remote controller 163 transmits the generated operation signal to the light receiving unit 162 by infrared communication. The light receiving unit 162 and the remote controller 163 may be configured to transmit and receive operation signals by other wireless communication such as radio waves.

  The card connector 164 is an interface for communicating with, for example, a memory card 165 that stores moving image content. The card connector 164 reads moving image content data from the connected memory card 165 and supplies it to the control unit 150.

  The USB connector 166 is an interface for communicating with the USB device 167. The USB connector 166 supplies a signal supplied from the connected USB device 167 to the control unit 150.

  For example, when the USB device 167 is an operation input device such as a keyboard, the USB connector 166 receives an operation signal from the USB device 167. The USB connector 166 supplies the received operation signal to the control unit 150. In this case, the control unit 150 executes various processes based on the operation signal supplied from the USB connector 166.

  For example, when the USB device 167 is a storage device that stores content data of a moving image, the USB connector 166 can acquire content from the USB device 167. The USB connector 166 supplies the acquired content to the control unit 150.

  The disk drive 170 has, for example, a drive on which a compact disk (CD), a digital versatile disk (DVD), a Blu-ray disk (BD), or another optical disk M capable of recording moving image content data can be mounted. The disk drive 170 reads content from the optical disk M to be loaded and supplies the read content to the control unit 150.

  The image processing apparatus 100 includes a power supply unit (not shown). The power supply unit supplies power to each unit of the image processing apparatus 100. The power supply unit converts, for example, power supplied via an AC adapter and supplies the converted power to each unit. Further, the power supply unit may include a battery. In this case, the power supply unit charges the battery with power supplied via an AC adapter or the like. The power supply unit supplies the power charged in the battery to each unit of the image processing apparatus 100.

  The image processing apparatus 100 may further include another interface. The interface is, for example, Serial-ATA, a LAN port, or the like. The image processing apparatus 100 can acquire and play back content recorded in a device connected by an interface. Further, the image processing apparatus 100 can output the reproduced audio signal and video signal to a device connected by an interface.

  Further, when the image processing apparatus 100 is connected to a network via an interface, the image processing apparatus 100 can acquire and reproduce moving image content data on the network.

  Furthermore, the image processing apparatus 100 may include a storage device such as a hard disk (HDD), a solid state disk (SSD), or a semiconductor memory. When the storage device stores moving image content data, the image processing device 100 can read and reproduce the content stored in the storage device. Further, the image processing apparatus 100 can store content supplied by, for example, a broadcast signal or a network in the storage device.

FIG. 2 shows an example of the overdrive processing unit 134 shown in FIG.
As illustrated in FIG. 2, the overdrive processing unit 134 includes a voltage value table 1341, a frame memory 1342, a temperature sensor 1343, a gain table 1344, and a multiplier 1345.

  The display processing unit 133 inputs the video signal (input signal) subjected to the image quality adjustment as described above to the overdrive processing unit 134. The input signal input to the overdrive processing unit 134 is supplied to the voltage value table 1341, the frame memory 1342, and the gain table 1344.

  The voltage value table 1341 stores the gradation (luminance) of a pixel in two consecutive frames (the previous frame and the subsequent frame) and the voltage value in association with each other. The voltage value table 1341 has, for example, the configuration shown in FIG.

  The vertical axis in FIG. 3 represents the luminance (gradation) value of a certain pixel in the previous frame. Further, the horizontal axis of FIG. 3 indicates the luminance (gradation) value in the subsequent frame of a certain pixel. Furthermore, the numbers shown in the cells (cells) in FIG. 3 indicate the voltage values applied to the pixels.

  The frame memory 1342 stores the luminance (gradation) values of pixels for one frame. That is, the frame memory 1342 stores the received input signal for one frame. When an input signal is continuously supplied to the frame memory 1342, the frame memory 1342 sequentially overwrites the input signal for one frame. Further, when receiving an input signal, the frame memory 1342 outputs the already stored input signal to the voltage value table 1341 and the gain table 1344.

  As a result, the input signal of a certain frame (following frame) and the input signal of the previous frame (previous frame) of this frame are supplied to the voltage value table 1341 and the gain table 1344.

  The voltage value table 1341 outputs voltage values corresponding to the gradation value of a pixel in the previous frame and the gradation value of the same pixel in the subsequent frame. That is, the voltage value table 1341 outputs a voltage value corresponding to a combination of the gradation value of the previous frame and the gradation value of the subsequent frame of a certain pixel.

  The temperature sensor 1343 detects the temperature of the display 300. For example, the temperature sensor 1343 detects the temperature of the liquid crystal panel of the display 300 and the like. The temperature sensor 1343 outputs the detected temperature value to the gain table 1344.

  The gain table 1344 stores the gradation (luminance) of a pixel in two consecutive frames (the previous frame and the subsequent frame) and a function in association with each other. That is, the gain table 1344 stores a function for each combination of the previous frame and the subsequent frame. The gain table 1344 has, for example, the configuration shown in FIG.

  The vertical axis in FIG. 4 represents the luminance (gradation) value of a certain pixel in the previous frame. Further, the horizontal axis of FIG. 4 indicates the luminance (gradation) value in the subsequent frame of a certain pixel. Furthermore, each symbol A to Y shown in each cell (cell) in FIG. 4 represents a function as shown in FIG.

FIG. 5 shows an example of a function of the gain table 1344.
The vertical axis shown in FIG. 5 indicates the gain value. Also, the horizontal axis shown in FIG. 5 indicates the temperature detected by the temperature sensor 1343. Here, examples of the function A, the function G, and the function M are shown. Since the response characteristics of the liquid crystal molecules decrease as the temperature decreases, the functions A, G, and M output a high value when the liquid crystal panel is at a low temperature and are low when the liquid crystal panel is at a high temperature. Set to output a value. The same applies to other functions shown in FIG.

  The gain table 1344 refers to a function corresponding to the luminance (gradation) value of a pixel in the previous frame and the luminance (gradation) value of the same pixel in the subsequent frame. Further, the gain table 1344 calculates a gain value by substituting the value of the temperature detected by the temperature sensor 1343 into the function being referred to. The gain table 1344 outputs the calculated gain value.

  Multiplier 1345 multiplies the output of voltage value table 1341 and the output of gain table 1344. That is, the multiplier 1345 multiplies the voltage value output from the voltage value table 1341 by the gain output from the gain table 1344. Multiplier 1345 outputs the multiplied value as an output signal.

  Note that the voltage value table 1341 performs the process of specifying the voltage value described above for each pixel in the frame. Further, the gain table 1344 performs the above-described processing for specifying the gain for each pixel in the frame. The multiplier 1345 sequentially multiplies the signals output from the voltage value table 1341 and the gain table 1344.

  With the above processing, the overdrive processing unit 134 can overdrive the video signal for one frame. Further, the overdrive processing unit 134 performs the overdrive every time a video signal frame is input. Thereby, the overdrive processing unit 134 can sequentially output the overdriven video signal.

FIG. 6 shows an example of overdrive.
The upper graph in FIG. 6 shows the relationship between luminance and time. The lower graph in FIG. 6 shows the relationship between voltage and time.

  A graph 601 shows a change in luminance when overdrive is not performed. In this case, as shown in FIG. 6, the luminance reaches the target luminance in a slow time of one frame. In this case, a value corresponding to the video signal, that is, a voltage corresponding to the target luminance is applied to the pixels of the liquid crystal panel for a display time of one frame.

  On the other hand, a graph 602 shows a change in luminance when overdrive is performed. In this case, as shown in FIG. 6, the luminance reaches the target luminance at an early time of one frame. In this case, the voltage indicated by the graph 603 is applied to the pixels of the liquid crystal panel.

  A graph 603 shows that a voltage higher than the voltage value corresponding to the target luminance is applied to the pixels of the liquid crystal panel during the time T from the beginning of the frame. That is, the overdrive processing unit 134 performs an overdrive so that a voltage having a value obtained by multiplying the voltage value output from the voltage value table 1341 by the gain output from the gain table 1344 is applied to the pixel during the time T. Do the drive.

  The overdrive processing unit 134 performs processing so that a voltage having a value corresponding to the target luminance (gradation) is applied to the pixel after the time T has elapsed from the beginning of the frame. Thereby, the overdrive processing unit 134 can change the pixel of the liquid crystal to the target luminance (gradation) at an earlier time in one frame.

  As described above, the image processing apparatus 100 according to the present embodiment includes the voltage value table 1341 that specifies voltage values based on the combination of the luminance (gradation) of the previous frame and the luminance (gradation) of the subsequent frame, A gain table 1344 for specifying a gain based on the combination of the brightness (gradation) of the previous frame and the brightness (gradation) of the subsequent frame and the temperature is provided. The image processing apparatus 100 detects the temperature of the display 300 and specifies the gain based on the detected temperature and the gain table 1344. Furthermore, the image processing apparatus 100 calculates a voltage value corrected by overdrive based on the voltage value output from the voltage value table 1341 and the gain.

  With this configuration, the image processing apparatus 100 can perform overdrive with higher accuracy in accordance with the combination of the luminance (gradation) of the previous and subsequent frames and the temperature of the liquid crystal. Thereby, a voltage with a more appropriate value can be applied according to the temperature of the liquid crystal. As a result, it is possible to improve the image quality of the video displayed on the display 300 and to reduce flickering and afterimages. As a result, an image processing apparatus and an image processing method that can realize higher image quality can be provided.

  When the display 300 is a liquid crystal display device capable of color display in which a plurality of pixels of a plurality of colors such as red, blue, and green are arranged, the overdrive processing unit 134 includes different voltage value tables 1341, And a gain table 1344.

  In addition, when the display speed of the display 300 can be switched by double drive, quadruple drive, or the like, the overdrive processing unit 134 may include a voltage value table 1341 and a gain table 1344 that are different for each drive speed. Good. That is, the overdrive processing unit 134 may include a voltage value table 1341 and a gain table 1344 that are different for each frame length of the video signal.

  With this configuration, the overdrive processing unit 134 can reduce flickering and afterimage even when liquid crystal response characteristics such as stereoscopic display (3D display) are required.

  Further, the overdrive processing unit 134 may include a plurality of temperature sensors 1343. In this case, the liquid crystal panel of the display 300 is divided into a plurality of regions, and the overdrive processing unit 134 detects the temperature for each of the divided regions. The overdrive processing unit 134 calculates the gain based on the luminance (gradation) of the frames before and after the pixel included in the divided area and the temperature detected from the area including the pixel. Thereby, the overdrive processing unit 134 can specify a more appropriate gain according to the temperature of the liquid crystal panel.

  In the above-described embodiment, the gain table 1344 has been described as having a configuration in which the luminance (gradation) of two consecutive frames of pixels and a function are stored in association with each other. However, the present invention is not limited to this configuration. For example, as illustrated in FIG. 7, the gain table 1344 may be configured to include, for each temperature, a table in which combinations of luminance (gradation) of pixels of two consecutive frames and gain values are associated with each other. .

FIG. 7 shows another example of the gain table 1344.
As shown in FIG. 7, the gain table 1344 includes a plurality of tables 1344A, 1344B, 1344C, and the like. The gain table 1344 may further include other tables.

  The vertical axis of each table in FIG. 7 indicates the luminance (gradation) value of a certain pixel in the previous frame. Further, the horizontal axis of each table in FIG. 7 indicates the luminance (gradation) value in the subsequent frame of a certain pixel. Furthermore, the numbers shown in the cells (cells) in FIG. 7 indicate gain values.

  Each table is associated with a value detected by the temperature sensor 1343. That is, the overdrive processing unit 134 selects a table from the gain table 1344 according to the temperature detected by the temperature sensor 1343. Further, the overdrive processing unit 134 reads the gain value from the table selected based on the luminance (gradation) of the previous frame and the luminance (gradation) of the subsequent frame. The overdrive processing unit 134 multiplies the read gain value by the value output from the voltage value table 1341 and outputs the result.

  Also with this configuration, the overdrive processing unit 134 can specify an appropriate gain value according to the temperature of the liquid crystal panel.

  In the above embodiment, the overdrive processing unit 134 has been described as multiplying the gain value output from the gain table 1344 by the voltage value output from the voltage value table 1341, but the present invention is not limited to this configuration. . The overdrive processing unit 134 may be configured to add the gain value output from the gain table 1344 to the voltage value output from the voltage value table 1341.

  The voltage value in the voltage value table 1341 and the function or gain value in the gain table 1344 are appropriately set according to the characteristics of the liquid crystal of the display 300 connected to the image processing apparatus 100. The values are not limited to those described in the embodiments.

  It should be noted that the functions described in the above embodiments are not limited to being configured using hardware, but can be realized by causing a computer to read a program describing each function using software. Each function may be configured by appropriately selecting either software or hardware.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Further, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, you may combine suitably the component covering different embodiment.

  DESCRIPTION OF SYMBOLS 100 ... Image processing apparatus, 101 ... Broadcast input terminal, 110 ... Antenna, 111 ... Tuner, 112 ... Demodulation unit, 113 ... Signal processing unit, 114 ... Communication interface, 121 ... Audio processing unit, 122 ... Audio output terminal, 131 ... Video processing unit, 132 ... OSD processing unit, 133 ... Overdrive processing unit, 134 ... Display processing unit, 135 ... Video output terminal, 150 ... Control unit, 151 ... CPU, 152 ... ROM, 153 ... RAM, 154 ... EEPROM, 161: Operation input unit, 162: Light receiving unit, 163: Remote controller, 164 ... Card connector, 165 ... Memory card, 166 ... USB connector, 167 ... USB device, 170 ... Disk drive, 200 ... Speaker, 300 ... Display, 1341 ... Voltage value table, 1342 ... Frame memory, 1 43 ... Temperature sensor, 1344 ... gain table, 1345 ... multiplier.

Claims (9)

An image processing apparatus for processing an image displayed on a liquid crystal panel in which a plurality of pixels are arranged in a matrix,
A temperature sensor for detecting the temperature of the liquid crystal panel;
A receiver for receiving a video signal;
A voltage value table that outputs a voltage according to a combination of gradations of consecutive previous and subsequent frames of the video signal received by the receiving unit;
A gain table for outputting a gain according to the combination of the luminance of the front frame and the rear frame and the temperature detected by the temperature sensor;
An overdrive output unit that performs overdrive based on the voltage output from the voltage value table and the gain output from the gain table, and outputs the overdriven voltage to the liquid crystal panel;
An image processing apparatus comprising:   2. The gain table according to claim 1, wherein a function for calculating a gain according to a temperature detected by the temperature sensor and a combination of gradations of the previous frame and the subsequent frame are stored in association with each other. The image processing apparatus described.   The image according to claim 2, wherein the overdrive output unit multiplies the voltage output from the voltage value table by the gain output from the gain table, and outputs the multiplied voltage to the liquid crystal panel. Processing equipment.   When the video signal includes signals for a plurality of colors, the gain table includes a function for calculating a gain according to the temperature detected by the temperature sensor, and gradations of the previous frame and the subsequent frame. The image processing apparatus according to claim 3, wherein a combination is stored in association with each color.   The gain table includes a function for calculating a gain according to the temperature detected by the temperature sensor and a combination of gradations of the previous frame and the subsequent frame for each frame length of the video signal. The image processing apparatus according to claim 3, wherein the image processing apparatus stores the information in association with each other.   The image according to claim 2, wherein the overdrive output unit adds the voltage output from the voltage value table and the gain output from the gain table, and outputs the added voltage to the liquid crystal panel. Processing equipment.   The image processing apparatus according to claim 1, wherein the gain table stores a combination of gradations of the previous frame and the rear frame and the gain in association with each temperature.   The image processing apparatus according to claim 1, further comprising a liquid crystal panel that displays an image based on a voltage output from the overdrive output unit. An image processing method used in an image processing apparatus that processes an image displayed on a liquid crystal panel in which a plurality of pixels are arranged in a matrix,
Detecting the temperature of the liquid crystal panel;
Receive video signal,
Output a voltage corresponding to the combination of gradations of successive previous and subsequent frames of the received video signal,
Output a gain according to the combination of gradations of the previous frame and the subsequent frame and the detected temperature,
Performing overdrive based on the voltage and the gain, and outputting the overdriven voltage to the liquid crystal panel;
Image processing method.

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