JP2013076855A - Video signal processing apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a video signal processing apparatus having reduced power consumption.SOLUTION: An input unit 2 executes video signal input processing of receiving an input video signal V1, performing A/D conversion, and outputting a horizontal synchronizing signal W-Hsync and a vertical synchronizing signal W-Vsync to a conversion unit 4 together with RGB data W-RGB. The conversion unit 4 executes a writing operation and a reading operation on a frame memory 3 to output RGB data R-RGB based on the RGB data W-RGB, a horizontal synchronizing signal R-Hsync, and a vertical synchronizing signal R-Vsync. When an operation mode signal SC7 received from external control means 7 indicates a power-saving mode, a microcomputer unit 1 gives a control signal SC11 to stop the video signal input processing in the input unit 2 and gives a control signal SC12 to stop the writing operation in the conversion unit 4.

Description

  The present invention relates to a video signal processing apparatus that performs predetermined video processing on an input video signal and outputs the video signal to predetermined video display means such as a liquid crystal display or a projector.

  In recent years, as represented by 1920 × 1200p, 1920 × 1080p, and the like, video display devices that display high-resolution video signals have become common. On the other hand, there are various resolutions (for example, 640 × 480, 1024 × 768, etc.) in the video source to be displayed, and there are also video signals output from a DVD player or the like.

  Therefore, a video signal processing circuit (device) that performs predetermined video processing on the video signal is required in order to perform video display on a video display device having high resolution. That is, a video signal processing apparatus is required which performs predetermined video processing on a predetermined input video signal and outputs an output video signal corresponding to predetermined video display means such as a liquid crystal display or a projector.

  Such a video signal processing device is required to operate on a large scale and at a very high speed in order to realize a function of outputting an output video signal corresponding to a high-resolution video display device. It is generally known that an AD converter, a frame memory, and a control device that controls the frame memory that constitute such a video signal processing apparatus generate a very large amount of heat as the speed increases. When each of these devices generates heat, the temperature within the printed circuit board on which each device is mounted and the set that contains the printed circuit board rises.If the temperature exceeds the operating temperature specified for each device, a malfunction occurs. Causes, such as causing, worst, and failure.

  For this reason, it is necessary to provide cooling means such as a fan inside to cool the temperature inside the set of the video signal processing apparatus. As a video signal processing apparatus provided with such a cooling means (fan), for example, there is an image projection apparatus disclosed in Patent Document 1.

JP 2009-288689 A

  In the video signal processing apparatus provided with the cooling means described above, it is possible to control the cooling means such as a fan in accordance with an input video signal (input video signal).

  However, the video signal processing apparatus generally operates on the premise of video processing for an input video signal for moving image display, and a video (for example, a still image such as an advertisement) that does not need to be frequently updated is displayed. In the case of displaying, there is a problem that wasteful power is consumed by operating even a circuit portion that is not substantially required for displaying a still image.

  The present invention has been made to solve the above problems, and an object of the present invention is to obtain a video signal processing apparatus that achieves low power consumption.

  According to a first aspect of the present invention, there is provided a video signal processing apparatus for outputting an output video signal which can be displayed on a predetermined display means, which receives the input video signal, and receives the input video signal. An input unit for performing video signal input processing and outputting video data for writing based on the above, a frame memory capable of writing and reading video data for at least one frame, and writing for writing the video data for writing to the frame memory A frame memory access unit that performs an operation and a read operation for reading the latest video data for writing written in the frame memory and obtaining video data for reading based on the video data for writing, and the video data for reading An output unit that performs video signal output processing based on the output video signal and outputs the output video signal, A video signal processing main unit is configured by the input unit, the frame memory, the frame memory access unit, and the output unit, and a power supply unit that supplies power to the video signal processing main unit, and the video signal by the input unit A control unit capable of controlling the write operation by the input processing and the frame access unit, the control unit receives an operation mode signal from the outside, and when the operation mode signal indicates a power saving mode, Power saving control for stopping the video signal input processing by the input unit and the writing operation in the frame memory access unit is executed.

  The control unit in the video signal processing device according to claim 1, when the operation mode signal indicates a power saving mode, the control unit performs the video signal input process and the video signal input operation and the write operation in the frame memory access unit. Power saving control to be stopped can be executed.

  Therefore, when it is not necessary to frequently update the video content displayed on the predetermined display means, that is, when it is not necessary to frequently change the content of the output video signal, the operation mode for instructing the power saving mode. By supplying a signal to the control unit from outside, the power supplied from the power supply unit to the input unit in the video signal processing main unit and the frame memory access unit is reduced by the amount of stopping the video signal input processing and the writing operation. Can be planned. At this time, since the conversion unit 4 performs the reading operation, the user of the predetermined display means can recognize the video displayed on the predetermined display means without a sense of incongruity.

It is a block diagram which shows the structure of the video signal processing apparatus which is Embodiment 1 of this invention. FIG. 6 is a timing chart showing the operation content in the normal mode of the video signal processing apparatus according to the first embodiment. FIG. 6 is a timing chart showing the operation content in the power saving mode of the video signal processing apparatus according to the first embodiment. FIG. 10 is a timing diagram showing the operation content in the power saving mode of the video signal processing device according to the second embodiment. It is a block diagram which shows the structure of the video signal processing apparatus which is Embodiment 3 of this invention. It is a block diagram which shows the structure of the video signal processing apparatus which is Embodiment 4 of this invention. It is a block diagram which shows the structure of the video signal processing apparatus which is Embodiment 5 of this invention. It is explanatory drawing which showed the internal structure of the video input board shown in FIG. 7, and a video output board. FIG. 10 is an explanatory diagram for a normal mode according to a fifth embodiment. FIG. 10 is an explanatory diagram for a power saving mode according to a fifth embodiment. FIG. 10 is a timing diagram showing the operation content in the power saving mode of the video signal processing device according to the fifth embodiment.

<Embodiment 1>
1 is a block diagram showing a configuration of a video signal processing apparatus according to Embodiment 1 of the present invention. FIG. 2 is a timing chart showing the operation contents of the video signal processing apparatus according to the first embodiment in the normal mode. FIG. 3 is a timing chart showing the operation contents of the video signal processing apparatus of the first embodiment in the power saving mode. .

  The video signal processing apparatus 100 includes a microcomputer unit 1 (control unit), an input unit 2, a frame memory 3, a conversion unit 4 (frame memory access unit), an output unit 5, a power supply unit 6, and an external control unit 7.

  The microcomputer unit 1 gives control signals SC11 and SC12 to the input unit 2 and the conversion unit 4, and controls video signal input processing by the input unit 2 and writing operation by the conversion unit 4.

  The input unit 2 receives the input video signal VI that is an analog signal, performs A / D conversion, and converts the horizontal synchronization signal W-Hsync and the vertical synchronization signal W-Vsync together with the RGB data W-RGB that is digital data. The video signal input process is executed. The RGB data W-RGB is data composed of 8-bit digital data, that is, 8-bit R digital data, 8-bit G digital data, and 8-bit B digital data. . The RGB data W-RGB becomes video data for writing to the frame memory 3. Thus, the input unit 2 functions as an A / D converter that converts the input video signal VI into RGB data W-RGB. The A / D converter is an example of the input unit 2.

  The frame memory 3 is a frame memory capable of storing RGB data W-RGB in a unit of one frame with a capacity of at least one frame.

  The conversion unit 4 is provided on the assumption that the input video signal VI is input at various resolutions and frequencies, and performs a write operation and a read operation on the frame memory 3.

  The conversion unit 4 executes the above-described write operation and read operation, thereby satisfying the target output resolution and output timing, and RGB data R-RGB (read-out video data), horizontal synchronization signal R-Hsync, and vertical synchronization. The signal R-Vsync is output. The conversion unit 4 outputs a write control signal SCW to the frame memory 3 during a write operation, and outputs a read control signal SCW to the frame memory 3 during a read operation.

  For example, when the RGB data M-RGB (RGB data W-RGB) has a resolution of 1024 × 768 and the vertical synchronization signal W-Vsync is 80 Hz, the output resolution is 1920 × 1200 and the vertical synchronization signal R-Vsync Will be described taking as an example the case of converting to 60 Hz.

  In this case, the conversion unit 4 executes a write operation for writing the RGB data W-RGB (resolution 1024 × 768) into the frame memory 3 as RGB data M-RGB in synchronization with the vertical synchronization signal W-Vsync (80 Hz). .

  Further, in parallel with the above write operation, the conversion unit 4 performs a read operation for reading the latest RGB data M-RGB (resolution 1024 × 768) from the frame memory 3 in synchronization with the vertical synchronization signal R-Vsync (60 Hz). Run.

  Further, RGB data R-RGB obtained by enlarging the read RGB data M-RGB to a resolution of 1920 × 1200 is output. At this time, the horizontal synchronizing signal R-Hsync and the vertical synchronizing signal R-Vsync (60 Hz) are also output. The RGB data R-RGB is composed of 8-bit R digital data, 8-bit G digital data, and 8-bit B digital data, similarly to the RGB data W-RGB.

  In this way, the conversion unit 4 performs resolution conversion on RGB data M-RGB (RGB data W-RGB) that is video data for writing, and obtains RGB data R-RGB that is video data for reading, and also performs vertical synchronization. A frame rate conversion is performed on the signal W-Vsync, and a vertical synchronization signal R-Vsync is output. In the above example, the writing operation is executed by writing the RGB data W-RGB into the frame memory 3 at an operating frequency of 80 Hz, and the reading operation is executed by reading the RGB data M-RGB at an operating frequency of 60 Hz. become. Since both the read operation and the write operation are performed in units of frames, 60 frames / 80 Hz of the data written in the frame memory 3, that is, 2 frames out of 8 frames of data written in the frame memory 3 are not read out. . 2 to 4 and FIG. 11 to be described later show a state where frame numbers thinned out due to a difference in operating frequency between the read operation and the write operation exist.

  Note that the resolution and output timing output by the conversion unit 4 can be easily changed by the control signal SC12 output from the microcomputer unit 1.

  The output unit 5 converts the RGB data R-RGB into a predetermined format and outputs it as an output video signal VO. In the first embodiment, the output unit 5 will be described as an example of a DVI (Digital Visual Interface) transmitter.

  The power supply unit 6 supplies the input unit 2, the frame memory 3, the conversion unit 4, and the output unit 5 with the input unit power source P 2, the frame memory power source P 3, the conversion unit power source P 4, and the output unit power source P 5. The microcomputer unit 1 and the external control unit 7 are supplied with power from another power source unit (not shown).

  The external control means 7 includes, for example, a changeover switch on the front panel of the video signal processing apparatus 100, and the user can switch the video signal processing apparatus 100 from the outside to the normal mode and the power saving mode. Means. An operation mode signal SC7 for instructing either the normal mode or the power saving mode is output from the external control means 7 to the microcomputer unit 1 in accordance with the switching operation contents by the user.

  When the operation mode signal SC7 indicates the normal mode, the microcomputer unit 1 gives the control signal SC11 to execute the video signal input processing by the input unit 2, and gives the control signal SC12 to write operation by the conversion unit 4 and A read operation (including a resolution conversion operation) is executed.

  On the other hand, when the operation mode signal SC7 indicates the power saving mode, the microcomputer unit 1 applies the control signal SC11 to stop the video signal input process by the input unit 2 and also applies the control signal SC12 to convert the conversion unit 4 The write operation by is stopped.

  The contents of the video signal processing operation performed by the video signal processing apparatus 100 according to the first embodiment having such a configuration will be described.

  An analog video signal output from a video card of a personal computer or the like is input as an input video signal VI to an input unit 2 composed of an AD converter or the like. Based on the input video signal VIi, the input unit 2 outputs, for example, 8-bit × 3 RGB data W-RGB, vertical synchronization signal W-Vsync, and horizontal synchronization signal W-Hsync as described above.

  In the conversion unit 4, for example, a horizontal synchronization signal R-Hsync of 74 KHz and a vertical synchronization signal R-Vsync of 60 Hz, for example, which are output timings of the video signal processing apparatus 100, are converted into the input video signal VI (RGB data W-RGB). A write operation and a read operation (including a conversion operation such as resolution) are executed so as to be always generated regardless of the resolution and frequency.

  First, the conversion unit 4 executes a writing operation in synchronization with the vertical synchronization signal W-Vsync, and sequentially converts the RGB data W-RGB based on the input video signal VI as RGB data M-RGB to the frame memory 3 in units of one frame. Write.

  Further, the conversion unit 4 performs a read operation in synchronization with the vertical synchronization signal R-Vsync in parallel with the write operation, and sequentially reads the latest RGB data M-RGB written in the frame memory 3 in units of one frame. To convert the frame rate. Thereafter, the RGB data M-RGB read by performing frame rate conversion is converted into RGB data R-RGB satisfying a resolution of 1920 × 1200, for example, and the vertical synchronization signal R-Vsync and the horizontal synchronization signal R- It is output to the output unit 5 together with Hsync.

  The output unit 5 constituted by a DVI transmitter converts the RGB data R-RGB into a DVI signal and outputs it as an output video signal VO which is an analog signal, whereby the output video signal VO is output by a predetermined display means such as a liquid crystal monitor. Allows video display based on.

  FIG. 2 shows the video signal processing operation of the video signal processing apparatus 100 in the normal mode in which the operation mode signal SC7 indicates the normal mode until the input video signal VI is finally output as the output video signal VO. It is the conceptual diagram which showed the process of.

  In the normal mode, the input unit 2 is always in an operating state and converts an input analog video signal into digital data, and outputs W-RGB data and W-Vsync, and W which is not shown in this figure. -Video signal input processing output by Hsync is always performed.

  Next, the conversion unit 4 always performs a write operation of the input RGB data W-RGB to the frame memory 3 and a read operation of the RGB data M-RGB from the frame memory 3 (including resolution conversion processing), The output unit 5 always outputs RGB data R-RGB, a vertical synchronization signal R-Vsync, and a horizontal synchronization signal R-Hsync (not shown in FIG. 2).

  Next, a case where the video signal processing apparatus 100 operates in the power saving mode will be described. FIG. 3 is a conceptual diagram showing a process until the input video signal VI, which is an analog video signal input in the power saving mode, is output from the video signal processing apparatus 100 as the output video signal VO, as in FIG. . In FIG. 3, the operation is performed in the normal mode until time t1, and the operation mode signal SC7 is switched from the normal mode to the power saving mode at time t1 by the user's operation using the external control means 7. Show.

  When the input video signal VI which is an input analog video signal is a still image such as an advertisement, for example, the user operates the external control means 7 to instruct the power saving mode from the external control means 7 as a switching command. A certain operation mode signal SC7 can be output. The operation mode signal SC7 is transmitted to the microcomputer unit 1, and the microcomputer unit 1 outputs a control signal SC11 instructing the stop to the input unit according to the contents of the power saving mode instruction of the operation mode signal SC7, and the video signal input by the input unit 2 Stop execution of the process.

  After that, the input unit 2 stops the video signal input processing unless the control signal SC11 instructing the stop cancellation (power saving mode cancellation) is issued from the microcomputer unit 1, so that the power consumption related to the operation of the input unit 2 is almost “ 0 ”.

  Then, the microcomputer unit 1 outputs the control signal SC12 to the conversion unit 4, thereby stopping the writing operation by the conversion unit 4 simultaneously with the video signal input process of the input unit 2 described above. At this time, the read operation by the conversion unit 4 is continued.

  As a result, since the conversion unit 4 executes only the read operation, the W-RGB data (RGB data M-RGB, FIG. 3) written in the frame memory 3 immediately before the instruction to stop the write operation by the control signal SC12 is transmitted. In the example, the frame number “2” is the latest data), and is repeatedly read from the frame memory 3 in units of one frame in synchronization with the vertical synchronization signal R-Vsync.

  As shown in FIG. 3, in the normal mode up to time t1, the video signal input process of the input unit 2 and the writing operation to the frame memory 3 are performed, but the mode is switched to the power saving mode by the user's operation. After the time t1, both (video signal input processing and writing operation) are stopped. Then, the RGB data W-RGB (RGB data M-RGB) of the frame number “2” written in the frame memory 3 immediately before the switching time t1 is repeatedly read in units of frames. In other words, on the predetermined display means visually recognized by the user, the video (still image or the like) with the frame number “2” is always displayed without a sense of incongruity.

  As described above, the microcomputer unit 1 of the video signal processing apparatus 100 according to the first embodiment controls the input unit 2 and the conversion unit 4 according to the power saving mode, so that the video by the input unit 2 in the power saving mode is obtained. By stopping the signal input process, the power consumption of the power supply P2 for the input unit supplied from the power supply unit 6 can be significantly reduced.

  In addition, the microcomputer unit 1 stops the writing operation by the conversion unit 4 in the power saving mode, so that the frame memory power supply P3 supplied to the frame memory 3 and the conversion unit power supply P4 supplied to the conversion unit 4 are also used. Since the write operation is not performed and only the read operation is performed, power can be significantly reduced.

  Therefore, the power amount of power supplied from the power supply unit 6 is greatly reduced by the power saving control by the microcomputer unit 11 that stops the video signal input process of the input unit 2 and the writing operation of the conversion unit 4. The power consumed by the entire apparatus 100 can be reduced.

  As described above, since the video signal processing apparatus 100 according to the first embodiment is configured, for example, an output video signal VO based on the input video signal VI that does not need to be frequently updated, such as a still image, is output. In this case, in the power saving mode, extra power consumption in the video signal processing apparatus 100 can be reduced. On the other hand, since the reading operation by the conversion unit 4 is executed, the user can visually recognize a video such as a still image displayed on the predetermined display unit based on the output video signal VO without a sense of incongruity.

  In the first embodiment, the microcomputer unit 11 outputs the control signals SC11 and SC12 to the input unit 2 and the conversion unit 4, thereby stopping the video signal input processing by the input unit 2 and the writing operation by the conversion unit 4. Power control was being executed. However, in general, the conversion unit 4 has a characteristic that the write operation is not automatically executed when the input signals (RGB data W-RGB, horizontal synchronization signal W-Hsync, and vertical synchronization signal W-Vsync) disappear. Yes. In the case of such a configuration, it is possible to execute power saving control for simultaneously stopping the writing operation by the conversion unit 4 by stopping only the video signal input process of the input unit 2 by the control signal SC11. Therefore, when the conversion unit 4 has the above characteristics, a mode in which only the video signal input process of the input unit 2 is stopped by the microcomputer unit 11 may be employed.

  In the first embodiment, the case where an analog video signal is input as the input video signal VI has been described. However, a YCbCr signal, a DVI signal, a high-speed serial signal such as a SERDES (Serializer Desirializer) signal, or the like is also described. The same effect can be obtained.

  In addition to the AD converter, the input unit 2 is a device that matches the type of video signal to be input, such as a DVI receiver, and is switched from the operation state to the stop state with respect to the video signal input process under the control of the microcomputer unit 1. However, the present invention is not limited to this as long as it can be easily performed.

  Further, in the first embodiment described above, the output resolution and output timing are described as an example of 1920 × 1200 @ 60 Hz (@ means vertical frequency), but other resolutions and output timings may be used. The same effect can be obtained even when converting to another video format such as YCbCr.

  In the first embodiment described above, an example in which the output unit 5 converts the signal into a DVI signal and outputs the signal has been described. However, the image is converted into another video format, for example, an analog video signal, a YCbCr signal, or a SERDES signal. Even when outputting, the same effect can be obtained.

  In the first embodiment described above, the effect when a still image is input has been described. However, the present invention is not limited to this, and a video that needs to be frequently updated in display content such as a moving image depending on the use environment and usage. Even in this case, by setting the power saving mode, it is possible to obtain the effect of reducing the power consumption of the entire assumption.

  In the above-described first embodiment, the switching to the power saving mode has been described by taking as an example a configuration in which the external control unit 7 including a switch or the like provided in the video signal processing apparatus 100 is used. Even if an external control device such as a personal computer is used instead of the external control means 7 to switch between the normal mode and the power saving mode, the same effect can be obtained.

  In the first embodiment described above, the video signal input process by the input unit 2 is stopped by the control signal SC11 from the microcomputer unit 1, but the input from the power supply unit 6 to the input unit 2 under the control of the microcomputer unit 1 It is also possible to stop the video signal input process by the input unit 2 by cutting off the supply of the unit power supply P2.

<Embodiment 2>
Next, the operation of the second embodiment will be described with reference to FIG. FIG. 4 is a timing diagram showing the operation contents of the video signal processing apparatus according to the second embodiment in the power saving mode.

  In the first embodiment, in the power saving mode, the same video (video based on RGB data W-RGB of frame number “2” in the example of FIG. 3) is repeated in units of one frame in synchronization with the vertical synchronization signal R-Vsync. The RGB data R-RGB was read out.

  The video signal processing apparatus 200 (not shown) of the second embodiment has the same hardware configuration as that of the video signal processing apparatus 100 of the first embodiment shown in FIG. 1, and the microcomputer unit 1 is programmed in advance as follows. This is a further improvement in convenience.

  FIG. 4 shows a process until the input video signal VI, which is an analog video signal input in the power saving mode in the video signal processing apparatus 200 according to the second embodiment, is output from the video signal processing apparatus 100 as the output video signal VO. It is the conceptual diagram which showed. 4 shows a state in which the operation is performed in the normal mode until the time t1, and the operation mode signal SC7 is switched to indicate the power saving mode at the time t1 by the user's operation using the external control unit 7. .

  As shown in FIG. 4, after the time t1 when the mode is switched to the power saving mode, the video signal from the input unit 2 is provided at certain time intervals (for example, every 10 minutes) under the control of the control signal SC11 from the microcomputer unit 1. The input process is controlled to stop → operation → stop. That is, in the power saving mode, the video signal input process is stopped while the video signal input process by the input unit 2 is intermittently executed at predetermined time intervals.

  Similarly, after time t1, under the control of the control signal SC12 from the microcomputer unit 1, the writing operation by the conversion unit 4 is controlled to stop → operation → stop at regular time intervals (for example, every 10 minutes). That is, in the power saving mode, the write operation is stopped while the write operation by the conversion unit 4 is intermittently executed at predetermined time intervals.

  As described above, the microcomputer unit 11 of the second embodiment is programmed so that the video signal input process by the input unit 2 and the write operation by the conversion unit 4 are intermittently executed even in the power saving mode.

  As shown in FIG. 4, since the microcomputer unit 1 intermittently operates the video signal input process by the input unit 2 and the write operation by the conversion unit 4 even in the power saving mode, a new W is input every 10 minutes. Since the RGB data is written in the frame memory 3 and repeatedly read out in units of one frame in synchronization with the vertical synchronization signal R-Vsync, the output video signal VO can be automatically updated at regular intervals. In the example of FIG. 4, immediately after time t1, the output video signal VO (RGB data R-RGB) is a signal based on the input video signal VI (RGB data W-RGB) of frame number “2”, and time t11 (time t1). 10 minutes after), the output video signal VO becomes a signal based on the input video signal VI of frame number “n”, and at time t12 (10 minutes after time t11), the output video signal VO is input video of frame number “m + 1”. The signal is based on the signal VI.

  As described above, the video signal processing apparatus 200 according to the second embodiment, like the video signal processing apparatus 100 according to the first embodiment, inputs the video signal by the input unit 2 when the operation mode signal SC7 indicates the power saving mode. The power consumption can be reduced by stopping the writing operation by the processing and conversion unit 4.

  Furthermore, the video signal processing apparatus 200 according to the second embodiment updates the video content displayed on the predetermined display means based on the output video signal VO periodically (every predetermined time interval) under the control of the microcomputer unit 11. Therefore, it is possible to cope with a video display whose content may be changed periodically although the frequency is low.

  In the second embodiment described above, an example in which the update for a certain period is performed by the control of the microcomputer unit 1 programmed in advance is not limited to this, and the inside of the external control means 7 is configured by a personal computer or the like, Even in a power saving mode, the same effect can be obtained by using the method in which the microcomputer unit 1 is controlled under the control of the external control means 7 and the video signal input processing and the writing operation are operated intermittently. .

  In Embodiment 2 described above, an example of the update interval is 10 minutes. However, as a matter of course, the update interval is not limited to this, and the same effect can be obtained at any interval. In addition, the update interval is lengthened during times when people do not often see images, such as at night, and the normal mode is maintained instead of the power saving mode, or updates in the power saving mode are performed during times that are frequently viewed. It is also possible to use various combinations depending on the usage environment and application, such as shortening the interval.

  Further, in the above-described second embodiment, it is more effective in the case of a video that requires frequent updating of the display content such as a moving image. For example, the display content is set at an update interval of, for example, every second. It is possible to reduce power consumption while updating.

<Embodiment 3>
FIG. 5 is a block diagram showing a configuration of a video signal processing apparatus 300 according to Embodiment 3 of the present invention.

  5 is a video signal processing device in which a cooling mechanism using a fan is added to the configuration of the video signal processing device 300 and the video signal processing device 100 of the first embodiment shown in FIG.

  The video signal processing main unit 20 shows a simplified main part including the input unit 2, the frame memory 3, the conversion unit 4, and the output unit 5 shown in FIG. The operations of the units 2 to 5 in the video signal processing main unit 20 until the input video signal VI, which is an analog video signal, is input and the output video signal VO is output are the same as those in the first embodiment (second embodiment). The operation is the same as that of the video signal processing apparatus 100 (200).

  As with the microcomputer unit 1 shown in FIG. 1, the microcomputer unit 11 sends the control signal SC20 (corresponding to the control signals SC11 and SC12 in FIG. 1) based on the operation mode signal SC7 to the video signal processing main unit 20 (inside the input unit 2 and It is output to the conversion unit 4).

  Further, the microcomputer unit 11 outputs a control signal SC30 for instructing the rotation speed of the fan 8 to the fan speed control unit 9.

  The power supply unit 12 is the same as the power supply unit 6 shown in FIG. 1, the main power source P20 for video signal processing (corresponding to the input unit power source P2, the frame memory power source P3, the conversion unit power source P4, and the output unit power source P5). Is supplied to the video signal processing main unit 20.

  Further, the power supply unit 12 supplies the fan speed control unit power supply P <b> 9 to the fan speed control unit 9.

  The fan 8 is provided for cooling the video signal processing main part 20, and the cooling speed is controlled as a result of the rotation speed being controlled by the fan speed control part 9. Specifically, the fan speed control unit 9 changes the rotation speed of the fan by changing the power supply voltage applied to the fan 8 based on the control signal SC30.

  A specific operation of the video signal processing apparatus 300 according to the third embodiment having such a configuration will be described. Also in the third embodiment, as in the first and second embodiments, the operation mode signal SC7 for instructing the power saving mode is output from the external control means 7 to the microcomputer unit 11, thereby controlling the microcomputer unit 11. Thus, the video signal processing main unit 20 (the input unit 2 and the conversion unit 4 thereof) is controlled.

  That is, when the operation mode signal SC7 indicates the power saving mode, the microcomputer unit 11 stops the video signal input processing of the input unit 2 in the video signal processing main unit 20 by the control signal SC20, and converts the frame memory 3 into a conversion unit. 4 is stopped.

  Therefore, it is clear that the heat generation amount of the video signal processing main unit 20 is smaller in the power saving mode than in the normal mode. Allowance to be reduced. Therefore, the microcomputer unit 11 outputs a control signal SC30 instructing to reduce the rotation speed of the fan 8 to the fan speed control unit 9, and controls the fan speed control unit 9 to reduce the cooling capacity of the fan 8. I am trying.

  As described above, since the video signal processing apparatus 300 according to the third embodiment operates, the power supplied to the video signal processing main unit 20 can be reduced in the power saving mode as in the first and second embodiments. Accordingly, the fan 8 can afford to reduce the cooling capacity.

  Therefore, the video signal processing apparatus 300 according to the third embodiment controls the fan speed control unit 9 with the control signal SC30, thereby reducing the cooling capacity of the fan 8 in the power saving mode as the power saving control. The power to be supplied can also be reduced.

  In addition, there is an effect that the life of the fan 8 can be extended by lowering the rotation speed in accordance with the reduction of the cooling capacity of the fan 8 and the life of the entire video signal processing apparatus 300 can be extended.

  In the third embodiment described above, an example in which the video signal processing main unit 20 is cooled by air cooling by the fan 8 has been described. However, the present invention is not limited to this, and other cooling methods such as Peltier are used instead of the fan 8. The same effect can be obtained even by a cooling method using an element.

<Embodiment 4>
FIG. 6 is a block diagram showing a configuration of a video signal processing apparatus 400 according to Embodiment 4 of the present invention.

  In FIG. 6, a video signal processing device 400 is a video signal processing device provided with four channels equivalent to the video signal processing main unit 20 described in FIG. 5 as the video signal processing main units 21 to 24.

  The video signal processing main units 21 to 24 assigned to 1ch to 4ch correspond to the video signal processing main unit 20 that inputs the input video signal VI and outputs the output video signal VO, respectively, shown in FIG. Accordingly, the video signal processing main unit 2i (i = 1 to 4) receives the input video signal VIi (corresponding to the input video signal VI) as in the video signal processing main unit 20, and outputs the output video signal VOi (output video). (Corresponding to the signal VO).

  The external control unit 13 is a unit corresponding to the external control unit 7 shown in FIG. 1, and switches the normal mode and the power saving mode of each of the video signal processing main units 21 to 24 individually by the operation of the user or the like. As described above, the control signal SC13 instructing the mode in each of the video signal processing main units 21 to 24 is output to the microcomputer unit 14.

  The microcomputer unit 14 outputs the control signals SC21 to SC24 to the video signal processing main units 21 to 24 in accordance with the instruction content of the control signal SC13. Control signals SC21 to SC24 correspond to control signal SC20 in video signal processing apparatus 300 of the third embodiment shown in FIG. That is, the microcomputer unit 14 outputs the control signals SC21 to SC24 to the video signal processing main units 21 to 24, so that the video signal processing main units 21 to 24 can be controlled independently in the power saving mode. .

  Further, the microcomputer unit 14 outputs a control signal SC30 for instructing the rotational speed of the fan 8 to the fan speed control unit 9 as in the microcomputer unit 11 of the third embodiment shown in FIG.

  The power supply unit 15 supplies video signal processing main part power supplies P21 to P24 (corresponding to the video signal processing main part power supply P20 of the third embodiment shown in FIG. 5) to the video signal processing main parts 21 to 24. The fan speed control unit 9 is supplied with the fan speed control unit power supply P9.

  The fan 8 and the fan speed control unit 9 are the same as those in the third embodiment shown in FIG.

  The operation of the video signal processing apparatus 400 according to the fourth embodiment having such a configuration will be described.

  As described above, the external control unit 13 can switch the video signal processing main units 21 to 24 from the normal mode to the power saving mode for each of the channels ch1 to ch4. An operation mode signal SC13 for instructing, that is, instructing a plurality of types of power saving modes is output to the microcomputer unit. The microcomputer unit 14 can individually control the video signal processing main units 21 to 24 of the channels ch1 to ch4 by the control signals SC21 to SC24. For example, the following combination control can be performed.

Ch1 video signal processing main part 21: normal mode,
Ch2 video signal processing main unit 22: normal mode,
Ch3 video signal processing main unit 23: normal mode,
Ch4 video signal processing main unit 24: power saving mode,
Combination control is possible.

Or
Ch1 video signal processing main unit 21: power saving mode,
Ch2 video signal processing main unit 22: power saving mode,
Ch3 video signal processing main unit 23: power saving mode,
Ch4 video signal processing main unit 34: power saving mode,
Combination control is also possible.

  As the number of channels set to the normal mode among the channels ch1 to ch4 increases, the number of devices that operate increases, so the amount of heat generation increases, and the temperature within the set of the video signal processing device 400 increases.

  Conversely, it is clear that the temperature in the set decreases as the number of channels set to the normal mode decreases. Therefore, the more the number of video signal processing main parts 2 i (i = 1 to 4) that are in the power saving mode, the smaller the air volume that is the cooling capacity of the fan 8. In response to the increase in the number of video signal processing main units 2i, the control signal SC30 is output to control the fan speed control unit 9 so as to decrease the rotation speed of the fan 8.

  As described above, since the video signal processing apparatus 400 according to the fourth embodiment operates, the operation mode of each channel (channels ch1 to ch4) can be individually switched to the power saving mode depending on the content of the displayed video. The power consumption of the entire apparatus can be reduced without adversely affecting the video signal processing in each of the plurality of video signal processing main units 2i.

  In addition, the video signal processing apparatus 400 according to the fourth embodiment can reduce the power consumption of the entire apparatus more effectively because the cooling capacity of the fan 8 is not excessive and can be minimized. is there.

  In addition, in the fourth embodiment, as in the third embodiment, the life of the fan 8 can be extended by lowering the rotational speed of the fan 8, and the entire life of the video signal processing apparatus 400 can be extended. .

  In Embodiment 4 described above, the case of four channels has been described as an example of a plurality of channels. However, the number of channels is not necessarily four, and the same effect can be obtained even in an arbitrary number of channels.

  In the fourth embodiment described above, one fan 8 and one fan speed control unit 9 have been described. However, a plurality of fans 8 and fan speed control units 9 may be provided. For example, among the plurality of fans, only a predetermined fan is selectively reduced in speed and the rotation speeds of the other fans are kept as they are. By effectively cooling according to the arrangement, it is possible to stabilize the operation of the video signal processing device 400 and reduce the power consumption.

  In the fourth embodiment described above, as in the third embodiment, the same effect can be obtained not by air cooling by the fan 8 but also by another cooling method, for example, a cooling method using a Peltier element or the like.

<Embodiment 5>
FIG. 7 is a block diagram showing a configuration of a video signal processing apparatus 500 according to Embodiment 5 of the present invention.

  The video signal processing apparatus 500 has a configuration in which a plurality of video input boards 51 to 5n and a plurality of video output boards 71 to 7m can be mounted. The video input boards 51 to 5n constitute a video input board group 50, and the video output boards 71 to 7m constitute a video output board group 70.

  FIG. 8 is an explanatory diagram showing internal configurations of the video input board 5i (i = 1 to n) and the video output board 7j (j = 1 to m) shown in FIG.

  As shown in FIG. 8, each video input board 5i has video signal processing main parts 31 to 34 (first type video signal processing main parts) for four channels mounted therein. Each video output board 7j is equipped with video signal processing main parts 41 to 44 (second type video signal processing main parts) for four channels. The video signal processing main units 31 to 34 and the video signal processing main units 41 to 44 correspond to the video signal processing main unit 20 of the third embodiment shown in FIG. 5, respectively. The input unit 2 shown in FIG. A frame memory 3, a conversion unit 4, and an output unit 5.

  In this way, the p (4 × n) video signal processing main units 31 to 34 are configured to be categorized as n video input boards 51 to 5n in units of four channels, and q (4 × m) video. The signal processing main parts 41 to 44 are configured to be classified into m video output boards 71 to 7m in units of four channels.

  As shown in FIG. 7, the video input boards 51 to 5n receive the board input video signals BVI1 to BVIn and output the intermediate output video signals MVO1 to MVOn to the matrix switch 60.

  The matrix switch 60 has p × q (p is the total number of intermediate output video signals to be input (first predetermined number), q is the total number of intermediate input video signals to be output (second predetermined number), and is greater than or equal to p, q1. (Integer) matrix switch.

  That is, the matrix switch 60 functions as a video signal converter that can switch and output each of the p intermediate output video signals MVO as any of the q intermediate input video signals MVI.

  The video output boards 71 to 7m receive the intermediate input video signals MVI1 to MVIm and output the board output video signals BVO1 to BVOn.

  The external control means 16 can individually set the plurality of video output boards 71 to 7m to the power saving mode by an external operation by the user, and further, the channel ch1 in each of the video output boards 71 to 7m. ˜ch4 can also be individually set to the power saving mode. That is, the external control means 16 can output to the microcomputer unit 17 the operation mode signal SC16 for instructing the video output boards 71 to 7m to select a plurality of types of power saving modes in which the minimum units are channels ch1 to ch4.

  The microcomputer unit 17 outputs the control signal SC50 to the video input board group 50, the control signal SC60 to the matrix switch 60, and the control signal SC70 to the video output board group 70 based on the operation mode signal SC16. The control signal SC50 is a control signal capable of power saving control for the video input boards 51 to 5n with the minimum unit as channels ch1 to ch4, and the control signal SC70 is for power saving control with the minimum unit as channels ch1 to ch4. This is a control signal possible for the video output boards 71 to 7m. The control signal SC70 is generated so as to enable power saving control with the minimum units of the channels ch1 to ch4 for the video output boards 71 to 7m corresponding to a plurality of power saving modes of the operation mode signal SC16. On the other hand, the control signal SC50 is based on a plurality of power saving modes of the operation mode signal SC16 and takes into account the signal switching contents of the matrix switch 60 indicated by the control signal SC60, and is the minimum unit for the video input boards 51 to 5n. Is generated in such a manner that power saving control can be performed with channels ch1 to ch4.

  Further, the microcomputer unit 17 outputs a control signal SC30 based on the operation mode signal SC16 to the fan speed control unit 9 and controls the cooling capacity of the fan 8 in the same manner as the microcomputer unit 11 of the third embodiment shown in FIG. ing.

  The power supply unit 18 supplies the video input board power P50 to the video input board group 50, supplies the matrix switch power P60 to the matrix switch 60, and supplies the video output board power P70 to the video output board group 70. Yes. Further, the power supply unit 18 supplies the fan speed control unit 9 with the power P9 for the fan speed control unit.

  The fan 8 and the fan speed control unit 9 are the same as those in the third embodiment shown in FIG.

  As shown in FIG. 8, the video input board 5i includes video signal processing main units 31 to 34 for channels ch1 to ch4, each corresponding to the video signal processing main unit 20 shown in FIG. The video signal processing main units 31 to 34 receive the input video signals VI31 to VI34 and output the output video signals VO31 to VO34.

  Similarly, the video output board 7j includes video signal processing main units 41 to 44 for channels ch1 to ch4, each of which corresponds to the video signal processing main unit 20 shown in FIG. The video signal processing main parts 41 to 44 receive the input video signals VI41 to VI44 and output the output video signals VO41 to VO44.

  Regarding the video input board 5i, the input video signals VI31 to VI34 correspond to the board input video signal BVIi shown in FIG. 7, and the output video signals VO31 to VO34 correspond to the intermediate output video signal MVOi shown in FIG. Further, regarding the video output board 7j, the input video signals VI41 to VI44 correspond to the intermediate input video signal MVIj shown in FIG. 7, and the output video signals VO41 to VO44 correspond to the board output video signal BVOj shown in FIG.

  FIG. 9 is an explanatory diagram for the normal mode in the fifth embodiment, and FIG. 10 is an explanatory diagram for the power saving mode in the fifth embodiment.

  In the video signal processing apparatus 500 according to the fifth embodiment, the video input board group 50 includes two video input boards 5i (the video input board 51 and the video input board 52), and the video output board group 70 includes two videos. The output board 7j (the video output board 71 and the video output board 72) is shown when the matrix switch 60 is 8 × 8.

  As shown in FIG. 9, the video signal processing apparatus 500 according to the fifth embodiment receives a plurality of video signals having different video formats inputted to the video input board 51 and the video input board 52, and receives the plurality of video signals. Using the video signal processing function of the video signal processing main units 31 to 34, it is converted into a constant SERDES signal, for example, and output as an intermediate output video signal MVO. Then, after being switched to the matrix switch (8 × 8) 60, it is output as an intermediate input video signal MVI to any one of the channels ch 1 to ch 4 of the video output boards 71 and 72.

  The video output board 71 and the video output board 72 use the video signal processing function of the video signal processing main units 41 to 44 for the input SERDES signal, and video signals of various desired formats and videos of the original format. The signal is restored and output as a board output video signal BVO.

  For example, the A still image (1024 × 768 @ 80 Hz) signal input to the input channel 1 of the video input board 51 is converted into a predetermined video format as described in the video signal processing apparatus 100 of the first embodiment. Thereafter, it is converted into, for example, a SERDES signal and output from the output ch1 as the output video signal VO31. This output video signal VO31 becomes a part of the intermediate output video signal MVO in FIG.

  Thereafter, the output video signal VO31 is output to the input ch1 and the input ch2 of the video output board 71 by the matrix switch 60 as the input video signals VI41 and VI42. These input video signals VI41 and VI42 become part of the intermediate input video signal MVI.

  The video signal processing main part 41 (ch1) of the video output board 71 converts the input SERDES signal into a video signal of 1920 × 1200 @ 60 Hz and outputs it as an output video signal VO41. Similarly, the video signal processing main unit 42 (ch2) of the video output board 71 converts the input SERDES signal into an 800 × 600 @ 60 Hz video signal and outputs it as an output video signal VO42. These output video signals VO41 and VO42 become part of the board output video signal BVO.

  The C video 1 (HDTV), which is the input video signal VI33 input to the video signal processing main unit 33 (ch3) of the video input board 51, is transmitted from the video signal processing main unit 41 (ch1) of the video output board 72 to 1024. It is converted into a video signal of x768 @ 60 Hz and output as an output video signal VO41.

  The C video 2 which is the input video signal VI34 input to the video signal processing main unit 34 (ch4) of the video input board 51 is 1024 × 768 @ 60 Hz from the video signal processing main unit 42 (ch2) of the video output board 72. And output as an output video signal VO42.

  Further, the signal of the D still image (640 × 480 @ 60 Hz) input as the input video signal VI31 to the video signal processing main unit 31 (ch1) of the video input board 52 is the video signal processing main unit 43 (ch3) of the video output board 72. ) And the video signal processing main part 44 (ch4) are converted into signals of 1920 × 1200 @ 60 Hz and output as output video signals VO43 and VO44.

  As described above, the video signal processing apparatus 500 shown in the fifth embodiment includes the switching control of the matrix switch 60, the video signal processing main units 31 to 34 of the video input board 5i, and the video signal processing main unit 41 of the video output board 7j. Each of the video signal processing functions of .about.44 is characterized in that a video input to an arbitrary input channel on the video input board 5i is output to an arbitrary output channel on the video output board 7j in an arbitrary video format.

  Here, since the input A, B, and D signals are still images, unnecessary operations are stopped and the power saving mode is performed as described in the first embodiment.

  FIG. 10 is a diagram showing the operation in the power saving mode as described above. Among the video signal processing main units 31 to 34 and 41 to 44, the video signal processing mains in which all the white space in the block is white. The video signal processing main unit, in which all the internal circuits are operating and the left half is filled with hatched hatching, stops the video signal input processing of the input unit 2 and the writing operation by the conversion unit 4 It shows that. Further, the main part of the video signal processing in which all the blanks in the block are filled with hatched lines shows a state in which the operation of all the internal circuits is stopped.

  For example, in the case of A still image, the content of the video to be displayed is written into the frame memory 3 of each of the video signal processing main parts 41 and 42 (ch1 and ch2) of the video output board 71 via the matrix switch 60. Therefore, it is possible to display without a sense of incongruity only by the reading operation from the frame memory 3.

  9 and FIG. 10, the A still image (1024 × 768 @ 80 Hz) is input as the input video signal VI31 in FIG. 9 and FIG. 10, and finally from the video signal processing main part 31 of the video input board 51 via the matrix switch 60. FIG. 6 is a schematic diagram illustrating a flow in which an A still image (1920 × 1200 @ 60 Hz) is output as the output video signal VO41 from the video signal processing main part 41 (ch1) of the video output board 71. FIG. 11 shows a state of switching from the time t2 to the power saving mode.

  Therefore, the entire circuit operation of the video signal processing main part 31 (ch1) of the video input board 51 and the video signal processing main parts 41 and 42 (ch1 and ch2) of the video output board 71 are performing video signal processing for the A still image. The video signal input processing by the input unit 2 and the writing operation to the frame memory 3 by the conversion unit 4 are unnecessary and can be stopped.

  In this case, for example, if the user operates the external control means 16 to indicate the power saving mode for the video signal processing main units 41 and 42 of the video output board 71 displaying the A still image, the microcomputer unit 17 Under control, power saving control can be performed not only on the video signal processing main units 41 and 42 of the video output board 71 but also on the video signal processing main unit 31 of the video input board 51 related to the A still image. This is because the microcomputer unit 17 outputs the control signal SC60 and recognizes the switching contents of the matrix switch 60.

  Similarly, in the case of the B still image, the entire circuit operation of the video signal processing main part 32 (ch2) of the video input board 51 and the video signal processing main parts 33 and 34 (ch3 and ch4) of the video output board 71 are input. The video signal input processing of the unit 2 and the writing operation to the frame memory 3 are not necessary and can be stopped.

  Next, the video signal processing main units 33 and 34 (ch3 and ch4) of the video input board 51 and the video signal processing main units 41 and 42 (ch1) of the video output board 72 are processed. And ch2) keep all the circuits in operation.

  Similarly, in the case of the D still image, the entire circuit operation of the video signal processing main part 31 (ch1) of the video input board 52 and the video signal processing main parts 33 and 34 (ch3 and ch4) of the video output board 72 are input. The video signal input processing of the unit 2 and the writing operation to the frame memory 3 are not necessary and can be stopped.

  Furthermore, since there is no input to the other channels of the video input board 52, the operation of the video signal input board 2 itself can be stopped collectively.

  As described above, since the video signal processing apparatus 500 according to the fifth embodiment operates, in the power saving mode, an unnecessary circuit portion or unnecessary is not required depending on the type and connection state of the input video signal. By stopping the operation of unnecessary channels and unnecessary boards, power consumption can be greatly reduced.

  Further, by stopping the operation of unnecessary portions, as described in the third and fourth embodiments, the temperature in the set in the video signal processing device 500 can be lowered, so that the fan speed control unit 9 It is possible to further reduce power consumption by controlling the above and lowering the rotation speed of the fan 8 to effectively cool the fan 8. Similarly to the third and fourth embodiments, the life of the entire video signal processing apparatus 500 can be extended by extending the life of the fan 8 by reducing the rotational speed of the fan 8.

  As described above, the microcomputer unit 17 in the video signal processing apparatus 500 according to the fifth embodiment uses the control contents of the operation mode signal SC16 and the control signal SC60 (switching contents of the matrix switch 60), respectively. Power saving control is performed independently for each video signal processing main unit for each video signal processing main unit 41 to 44 of each of the video signal processing main units 31 to 34 and the video output boards 71 to 7m.

  For this reason, the video signal processing apparatus 500 according to the fifth embodiment reduces the power consumption of the entire apparatus without adversely affecting the processing of each main part of the video signal processing in the video input board group 50 and the video output board group 70. can do.

  Furthermore, since the microcomputer unit 17 in the video signal processing apparatus 500 according to the fifth embodiment can execute power saving control in units of the video input boards 51 to 5n and the video output boards 71 to 7m, it can be efficiently performed. The power saving control can be efficiently performed.

  In the above-described fifth embodiment, a case has been described in which a channel for processing a still image stops unnecessary circuits as shown in the first embodiment and a channel for processing a moving image performs a normal operation. It is not limited to. For example, the channel for processing a video is also operated in the power saving mode, and the display content is updated at a constant interval as shown in the second embodiment. The operation mode of each channel of each board depends on the use environment and application. May be used separately.

  In the above-described fifth embodiment, the video input board 5i and the video output board 7j have been described with respect to an example in which four channels of the main part of the video signal processing are mounted. The number may be any number of channels.

  In the above-described fifth embodiment, the example in which two video input boards 5i and two video output boards 7j are mounted in FIGS. 9 and 10 has been described.

  Further, in the fifth embodiment described above, as in the third and fourth embodiments, a configuration is provided in which a plurality of fans and a fan speed control unit are provided, and the rotational speed of a specific fan is reduced. While the speed of the rotation speed of the fans other than the above is kept as it is, the cooling of the video signal processing apparatus is stabilized by effectively cooling according to the number of video input boards 5i and video output boards 7j and the arrangement in the set. It is also possible to reduce power consumption.

  Further, in the fifth embodiment described above, similar to the third and fourth embodiments, the same effect can be obtained not by air cooling by a fan but also by another cooling method, for example, a cooling method using a Peltier element or the like. it can.

  It should be noted that the present invention can be freely combined with each other within the scope of the invention, and each embodiment can be appropriately modified or omitted.

  As an application example of the video signal processing apparatus of the present invention, it can be used for a video signal processing apparatus for displaying a video for a long time.

  1, 11, 14, 17 Microcomputer unit, 2 input unit, 3 frame memory, 4 conversion unit, 5 output unit, 6, 12, 15, 18 power supply unit, 7, 13, 16 external control means, 8 fans, 9 fans Speed control part, 20-24, 31-34, 41-44 Video signal processing main part, 51-5n Video input board, 60 matrix switch, 71-7m video output board, 100-500 video signal processing apparatus.

Claims (6)

A video signal processing apparatus that outputs an output video signal that can be displayed on a predetermined display means,
An input unit that receives an input video signal, performs video signal input processing based on the input video signal, and outputs video data for writing;
A frame memory capable of writing and reading video data for at least one frame;
A write operation for writing the video data for writing to the frame memory and a read operation for reading the latest video data for writing written in the frame memory and obtaining video data for reading based on the video data for writing are performed. A frame memory access unit;
An output unit that performs video signal output processing based on the readout video data and outputs the output video signal, and the video signal processing is performed by the input unit, the frame memory, the frame memory access unit, and the output unit. The main part
A power supply unit for supplying power to the video signal processing main unit;
A control unit capable of controlling the video signal input processing by the input unit and the writing operation by the frame access unit;
The control unit receives an operation mode signal from the outside, and when the operation mode signal indicates a power saving mode, the control unit stops the video signal input processing by the input unit and the writing operation in the frame memory access unit. It is characterized by executing control,
Video signal processing device. The video signal processing apparatus according to claim 1,
The power saving control by the control unit is configured such that when the operation mode signal indicates a power saving mode, the video signal input process and the writing operation are intermittently executed at predetermined time intervals. And a control for stopping the write operation,
Video signal processing device. The video signal processing device according to claim 1 or 2,
A cooling mechanism for performing a cooling operation for cooling at least the input unit and the frame memory access unit in the video signal processing main unit;
The control unit can further control the cooling operation of the cooling mechanism,
The power saving control includes control for reducing cooling capacity by the cooling operation in the cooling mechanism,
Video signal processing device. The video signal processing device according to any one of claims 1 to 3,
The video signal processing main part includes a plurality of video signal processing main parts,
Each of the plurality of video signal processing main units includes the input unit, the frame memory, the frame memory access unit, and the output unit,
The operation mode signal includes a signal indicating a plurality of types of power saving modes corresponding to the plurality of video signal processing main parts,
The control unit executes the power saving control individually for each of the plurality of video signal processing main units based on the operation mode signal.
Video signal processing device. The video signal processing device according to any one of claims 1 to 3,
The video signal processing main part includes a first predetermined number of first type video signal processing main parts and a second predetermined number of second type video signal processing main parts,
The first predetermined number of first-type video signal processing main units each include the input unit, the frame memory, the frame memory access unit, and the output unit,
The second predetermined number of second-type video signal processing main units each include the input unit, the frame memory, the frame memory access unit, and the output unit,
The video signal processing device includes:
The output video signals respectively obtained from the first predetermined number of first-type video signal processing main parts are received as a first predetermined number of intermediate output video signals, and each of the first predetermined number of intermediate output video signals is received. Is further provided with a video signal conversion unit capable of switching and outputting as any of the second predetermined number of intermediate input video signals,
The second predetermined number of second-type video signal processing main parts respectively receive the second predetermined number of intermediate input video signals as the input video signals,
The operation mode signal includes a signal indicating a plurality of types of power saving modes corresponding to the second predetermined number of second-type video signal processing main parts,
The control unit is capable of controlling the switching output content of the video signal conversion unit, and based on the operation mode signal and the switching output content of the video signal conversion unit, the first predetermined number of first type video signal processing mains The power saving control individually for each of the second predetermined number of second-type video signal processing main units,
Video signal processing device. The video signal processing apparatus according to claim 5,
The first predetermined number of first type video signal processing main parts are configured to be categorized as at least one input board,
The second predetermined number of second-type video signal processing main parts are configured to be categorized as at least one output board,
The control unit collectively executes the power saving control for each of the at least one input board and the at least one output boat based on the operation mode signal.
Video signal processing device.

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