JP2012230231A - Display control device and method of controlling the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology capable of receiving a plurality of image signals and displaying a plurality of images on a display based on the plurality of image signals with a small power consumption.SOLUTION: A display control device is capable of receiving a plurality of image signals from a connected external device and displaying a plurality of images on a display based on the plurality of image signals. The display control device includes: a plurality of receiving circuits for receiving the plurality of image signals; detection means for detecting the signal reception at each receiving circuit; and control means for controlling supply/non-supply of a driving power to each receiving circuit. The external device outputs a master sync signal from one output terminal at start-up, and then outputs the plurality of image signals from a plurality of output terminals. The control means supplies the driving power only to the receiving circuit which receives the master sync signal, and when the reception of the master sync signal is detected by the detection means, the control means starts supplying the driving power to other receiving circuits.

Description

  The present invention relates to a display control device and a control method thereof.

  Some monitors (display devices) with a high display resolution can display a single image by combining a plurality of input signals. For example, a 4K2K monitor has been put into practical use. “4K2K” is a name for a resolution of about 4,000 horizontal pixels × 2,000 vertical pixels. For example, when four divided image signals obtained by dividing one image are input as in a 4K2K monitor, one receiving circuit is required for each input signal. Two receiving circuits are required.

  Even when a plurality of input signals are combined to display an image, a mechanism for automatically switching the display according to the presence or absence of an input signal is required, as in the case of displaying an image with one input signal.

  Patent Document 1 discloses a method of automatically switching an input signal path according to the presence or absence of an input signal in a circuit that switches input signal paths from a plurality of different signal terminals. By using this method, when there is no input signal and the monitor is in the standby state, the presence or absence of the input signal at each input terminal is monitored, and the monitor is triggered by the detection of any input signal. It is possible to return from the standby state.

JP-A-6-51729

  However, when the monitor is returned to the standby state using the above-described existing technology, it is necessary to supply driving power (power for driving) to all receiving circuits and detect an input signal. Therefore, standby power corresponding to the number of receiving circuits is required, and there is a problem that power consumption increases.

  An object of the present invention is to provide a technique capable of reducing power consumption of a display control apparatus that can receive a plurality of image signals and display a plurality of images based on the plurality of image signals on a display unit.

The display control device of the present invention
A display control device capable of receiving a plurality of image signals from a connected external device and displaying a plurality of images based on the plurality of image signals on a display unit,
A plurality of receiving circuits for receiving a plurality of image signals;
Detection means for detecting reception of a signal in each receiving circuit;
Control means for controlling supply / non-supply of drive power of each receiving circuit;
Have
The external device outputs a plurality of image signals from a plurality of output terminals after outputting a master sync signal from one output terminal at startup,
The control means includes
Supply drive power only to the receiving circuit that receives the master sync signal,
When reception of the master sync signal is detected by the detecting means, supply of driving power to another receiving circuit is started.

The display device control method of the present invention includes:
A control method for a display control apparatus capable of receiving a plurality of image signals from a connected external device and displaying a plurality of images based on the plurality of image signals on a display unit,
A receiving step of receiving a plurality of image signals by a plurality of receiving circuits;
A detection step of detecting reception of a signal at each receiving circuit;
A control step for controlling supply / non-supply of drive power of each receiving circuit;
Have
The external device outputs a plurality of image signals from a plurality of output terminals after outputting a master sync signal from one output terminal at startup,
In the control step,
Supply drive power only to the receiving circuit that receives the master sync signal,
When reception of a master sync signal is detected in the detection step, supply of driving power to another receiving circuit is started.

  ADVANTAGE OF THE INVENTION According to this invention, the power consumption of the display control apparatus which can receive a some image signal and can display the some image based on a some image signal on a display part can be reduced.

Functional configuration of display control apparatus according to embodiment 1 and system configuration according to embodiment 1 Display screen of display control apparatus according to embodiment 1 System status according to the first and second embodiments Master Sync Receiver Circuit Specific Information According to Embodiment 1 Processing flow of display control apparatus according to embodiment 1 Flowchart of Master Sync Receiving Circuit Specifying Process According to Embodiment 1 Flowchart of reception monitoring processing according to the first embodiment. Block diagram of display control apparatus according to second embodiment and system configuration according to second embodiment Relationship between system status and receiving circuit state according to the second embodiment Contents of receiving circuit information storage area according to embodiment 2 Processing flow of display control apparatus according to embodiment 2 Flow chart of grouping processing according to embodiment 2 Flowchart of reception monitoring processing according to the second embodiment.

First, the definition of the term “master sync signal” used below will be described.
Hereinafter, a signal output from one output terminal when the external device is activated (first) is referred to as a master sync signal. When the external device is an external device that can output a plurality of image signals from a plurality of output terminals, the external device outputs a master sync signal from one output terminal at the time of startup, and then a plurality of image signals from the plurality of output terminals. Is output. The external device is, for example, a hard disk recorder, a Blu-ray disc recorder (player), a personal computer, or the like. The master sync signal may be any signal, for example, an image signal or a signal representing information on an external device. For example, the master sync signal is an image signal representing a BIOS (Basic Input / Output System) screen, an image signal representing a manufacturer's logo screen, or the like. Hereinafter, a receiving circuit that receives a master sync signal is referred to as a “master sync receiving circuit”.
In the present embodiment, it is assumed that the plurality of image signals output from the external device are signals of a plurality of divided images obtained by dividing one image.

Hereinafter, specific embodiments of a display control device and a control method thereof according to the present invention will be described in detail with reference to the drawings.
The display control apparatus according to the present embodiment is an apparatus that can receive a plurality of image signals from a connected external device and display images based on the plurality of image signals on a display unit.

<Example 1>
FIG. 1A is a block diagram illustrating an example of a functional configuration of the display control apparatus 100 according to the first embodiment of the present invention. The display control apparatus 100 includes reception circuits 101 to 104, a reception detection unit 105, a control unit 106, a storage unit 107, a signal processing unit 108, a display unit 109, and the like. In this embodiment, the display control apparatus 100 is connected to a personal computer, and a plurality of image signals are input to the display control apparatus 100 from the personal computer.

  Each of the receiving circuits 101 to 104 receives an image signal. In the present embodiment, the receiving circuits 101 to 104 receive an image signal conforming to the DVI (Digital Visual Interface) standard output from a personal computer, and perform serial-parallel conversion processing and synchronization separation processing on the received image signal. Specifically, the receiving circuits 101 to 104 receive image signals via the input terminals 1 to 4, respectively. The receiving circuits 101 to 104 perform the above processing on the received image signal, and output the image signal subjected to the above processing to the reception detection unit 105 and the signal processing unit 108. In this embodiment, the case where the image signal is a DVI standard image signal is taken as an example, but the image signal may be another type of image signal (for example, an HDMI standard image signal). .

  The reception detection unit 105 detects reception of a signal at each reception circuit by detecting a signal from each reception circuit. In this embodiment, the reception detection unit 105 generates signal presence / absence information from the signals input from the reception circuits 101 to 104 and outputs the signal presence / absence information to the control unit 106. When the signal input from the reception circuit is an image signal, the reception detection unit 105 generates image signal information corresponding to the reception circuit to which the image signal is input, and outputs the image signal information to the control unit 106. The signal presence / absence information is information indicating the presence / absence of a signal to each receiving circuit (whether the signal is received by each receiving circuit). The image signal information is information representing the format and synchronization timing of the input image signal. The signal presence / absence information may be information for each receiving circuit, or may be information specifying only a receiving circuit that receives an image signal or a receiving circuit that does not receive an image signal. .

The control unit 106 controls supply / non-supply of driving power (power for driving) of each receiving circuit. A specific control method for supplying / non-supplying driving power will be described in detail later.
Further, the control unit 106 acquires master sync receiving circuit specifying information from the storage unit 107. The master sync receiving circuit specifying information is information specifying the master sync receiving circuit. When the master sync receiving circuit specifying information is an initial value (when the master sync receiving circuit is not specified), the control unit 106 follows the master sync receiving circuit specifying process flowchart shown in FIG. Is identified. Then, the specifying result is stored in the storage unit 107 as master sync receiving circuit specifying information. The master sync receiving circuit specifying process will be described in detail later.

The storage unit 107 stores master sync receiving circuit specifying information in response to an instruction from the control unit 106. In addition, the storage unit 107 outputs master sync receiving circuit specifying information to the control unit 106 in response to an instruction from the control unit 106. As the storage unit 107, a magnetic disk, a volatile memory, a nonvolatile memory, or the like can be used.

The signal processing unit 108 outputs the image signal input from the receiving circuit to the display unit 109. In addition, when a plurality of image signals are input, the signal processing unit 108 synthesizes these images and outputs them to the display unit 109. In the present embodiment, the signal processing unit 108 synthesizes four image signals input from the receiving circuits 101 to 104 and outputs them to the display unit 109.
The display unit 109 displays an image based on the image signal input from the signal processing unit 108. As the display unit 109, a liquid crystal display, a plasma display, an organic EL display, a display having an electron-emitting device (or a display panel thereof), or the like can be used. The display unit 109 may be a part of the display control apparatus 100 or may be a separate device from the display control apparatus 100.

  In the present embodiment, the display control device, when image signals are input to a plurality of input terminals, those image signals are signals of a plurality of divided images obtained by dividing one image. The display is determined and displayed, but the configuration of the display control device is not limited to this. For example, it is possible to switch between a method of combining a plurality of image signals and displaying them on one screen and a different display method (for example, a method of displaying images based on a plurality of different image signals on one screen) by changing the setting. It may be a simple configuration.

FIG. 1B is a schematic diagram illustrating an example of a system configuration according to the first embodiment. As described above, this system includes the display control device 100 and the personal computer 200.
The display control apparatus 100 is connected to the personal computer 200 using four DVI cables. Specifically, the display control apparatus 100 has input terminals 1 to 4, and the personal computer 200 has DVI signal output terminals 201 to 204. One end of each of the four DVI cables is connected to the four input terminals 1 to 4, and the other end is connected to the DVI signal output terminals 201 to 204. The personal computer 200 has a function of outputting a signal of one image (a high-resolution image such as a 4K2K image) by outputting a DVI signal (image signal) from each of the four DVI signal output terminals 201 to 204. The image signal output from the personal computer 200 is input to the display control apparatus 100 (specifically, the input terminal of the display control apparatus 100) via the DVI cable.

FIG. 2 is a diagram illustrating an example of a display screen of the display control apparatus 100 when the personal computer 200 is activated according to the first embodiment.
The personal computer 200 outputs an image signal (master sync signal) representing the BIOS screen from the DVI signal output terminal 201 at the time of activation. The output image signal is input to the receiving circuit 101 (master sync receiving circuit) via the input terminal 1. Then, after predetermined processing is performed by the receiving circuit 101 and the signal processing unit 108 as necessary, the signal is input to the display unit 109. As a result, an image (BIOS screen) is displayed in the area 301 of the screen of the display unit 109.

  Thereafter, the personal computer 200 performs division output setting, and outputs signals of four divided images from the DVI signal output terminals 201 to 204. The image signals output from the DVI signal output terminals 201 to 204 are input to the receiving circuits 101 to 104 via the input terminals 1 to 4, respectively. Then, after predetermined processing is performed by the receiving circuits 101 to 104 and the signal processing unit 108, the signals are input to the display unit 109. As a result, an image is displayed in areas 301 to 304 of the screen of the display unit 109 (that is, the entire screen). The displayed image is an image obtained by combining the four divided images. The divided output setting is a setting for outputting signals of a plurality of divided images obtained by dividing one image. The divided output setting may be automatically performed or may be performed according to a user operation.

FIG. 3 is a diagram illustrating an example of the contents of the system status that the display control apparatus 100 according to the first embodiment can take.
The display control apparatus 100 according to the first embodiment has two states, a power-on state and a standby state. The power-on state is a state in which a signal is input and driving power is supplied to all functional units necessary for image display. The standby state is a state in which no signal is input and driving power is supplied to at least a function unit necessary for detecting input (reception) of the signal.

FIG. 4 is a diagram illustrating an example of master sync receiving circuit specifying information according to the first embodiment.
The set value “0” of the master sync receiving circuit specifying information is an initial value and indicates that the master sync receiving circuit is not specified. The set value “1” indicates that the receiving circuit 101 is a master sync receiving circuit. “2” represents the receiving circuit 102, “3” represents the receiving circuit 103, and “4” represents that the receiving circuit 104 is a master sync receiving circuit.

FIG. 5 is a flowchart illustrating an example of a processing flow when the main power source of the display control apparatus according to the first embodiment is turned on.
First, when the main power is turned on, the control unit 106 supplies driving power to each functional unit necessary for image display (S601), and sets the system status to the power-on state (S602).
Next, the control unit 106 acquires master sync receiving circuit specifying information from the storage unit 107 (S603). When the acquired master sync receiving circuit specifying information is “0”, the control unit 106 performs the master sync receiving circuit specifying process (S605), and then advances the process to S606. If it is other than “0”, the control unit 106 advances the process to S606 without performing the master sync receiving circuit specifying process.
In S606, the control unit 106 repeatedly performs the reception monitoring process (S607) while the main power of the display control device 100 is turned on.

FIG. 6 is a flowchart illustrating an example of the master sync receiving circuit specifying process (S605) according to the first embodiment. In this embodiment, the master sync receiving circuit is specified when the BIOS screen as shown in FIG. 2 is displayed.
First, the control unit 106 determines from the detection result (signal presence / absence information) of the reception detection unit 105 whether a signal is received by the receiving circuit to be processed (S703).
When the signal is received by the receiving circuit to be processed, the control unit 106 specifies the receiving circuit as a master sync receiving circuit, and stores the specifying result in the storage unit (S704). Then, the master sync receiving circuit specifying process ends. When the signal is not received by the receiving circuit to be processed, the control unit 106 switches the receiving circuit to be processed to the next receiving circuit, and performs the processing from S703 (S702). The loop process of S702 is repeated until a receiving circuit receiving a signal is found. In the example of FIG. 6, the processing is sequentially performed from the receiving circuit 101 corresponding to the input terminal 1 to the receiving circuit 104 corresponding to the input terminal 4. Thereafter, when the loop processing of S702 is performed, the receiving circuit 101 corresponding to the input terminal 1 is a processing target.

As described above, in this embodiment, when the receiving circuit that receives the master sync signal is not specified, the driving power is supplied to all the receiving circuits (S601). Then, the reception circuit in which reception of the signal is first detected by the reception detection unit 105 is specified as the reception circuit that receives the master sync signal.
Information regarding the master sync receiving circuit may be stored in advance in the display control device.
In this embodiment, the configuration in which the master sync receiving circuit specifying process is performed with the system status set to the power-on state has been described, but the configuration is not limited thereto. For example, the system status may be set to a standby state in which driving power is supplied to some functional units including all receiving circuits, and the master sync receiving circuit specifying process may be performed in this state.

FIG. 7 is a flowchart illustrating an example of the reception monitoring process (S607) according to the first embodiment. This process is repeated while the main power is on.
First, the control unit 106 uses the detection result of the reception detection unit 105 to monitor whether the master sync reception circuit has received a signal (S801).
When reception of the signal at the master sync receiving circuit is no longer detected by the reception detection unit 105, the control unit 106 stops supplying drive power to other receiving circuits (receiving circuits other than the master sync receiving circuit). (S802). Then, the control unit 106 sets the system status to the standby state (S803).
When the reception detection unit 105 detects reception of a signal in the master sync reception circuit, the control unit 106 supplies drive power to all the reception circuits (S804). Then, the system status is set to the power-on state (S805). That is, in this embodiment, the control unit 106 supplies driving power only to the master sync receiving circuit, and when the reception detecting unit 105 detects reception of the master sync signal, it supplies driving power to other receiving circuits. To start.

As described above, according to the present embodiment, the driving power is supplied only to the master sync receiving circuit, and when the reception of the master sync signal is detected, the supply of the driving power to the other receiving circuits is started. . Accordingly, it is possible to receive a plurality of image signals with low power consumption and display a plurality of images based on the plurality of image signals on the display unit. Specifically, the power consumption until a signal is received can be reduced as compared with the prior art.
Further, according to this embodiment, when the reception of a signal in the master sync receiving circuit is not detected, the supply of driving power to the other receiving circuits is stopped. Thereby, power consumption can be further reduced. Specifically, power consumption from when a signal is no longer received until the signal is received again can be reduced as compared with the prior art.
That is, according to the present embodiment, the power consumption in the standby state can be reduced as compared with the prior art.

In this embodiment, it is assumed that the connection state between the display control device 100 and the personal computer 200 and the settings of the personal computer 200 are fixed, and the master sync receiving circuit is fixed. Therefore, in this embodiment, the master sync receiving circuit specifying information is stored in the storage unit 107, and the master sync receiving circuit specifying process is performed only once. However, it is conceivable that the master sync receiving circuit is changed depending on the connection state and the setting of the personal computer 200. Therefore, in consideration of the change of the master sync receiving circuit, the master sync receiving circuit specifying process is displayed every time the main power of the display control device is turned on, or the connection state change between the display control device 100 and the personal computer 200 is displayed. The configuration may be performed every time the control device detects.
In this embodiment, a case has been described in which a plurality of image signals output from an external device are signals of a plurality of divided images obtained by dividing one image. However, an image signal is a signal of a divided image. Not necessarily. For example, the plurality of image signals may be signals of a plurality of different images. A part of the plurality of image signals may be a signal of one image, and the rest may be a signal of a divided image. Specifically, of the four image signals output from the external device, two signals are divided image signals obtained by dividing one image into two, and the remaining two signals are respectively It may be a single image signal.

<Example 2>
In the first embodiment, the case where one external device is connected to the display control device has been described. In the present embodiment, a case where a plurality of external devices can be connected to the display control device will be described.
As shown in FIG. 8A, the display control apparatus 400 according to the second embodiment includes more input terminals and receiving circuits (six input terminals 1 to 6 and six input terminals than the display control apparatus according to the first embodiment. Receiving circuits 401 to 406).
Note that the processes performed by the functional units other than the control unit 408 are the same as those in the first embodiment, and thus the description thereof will be omitted.

  The control unit 408 acquires the image signal information from the reception detection unit 407, and receives the group information of the reception circuit and the master sync reception circuit specifying information in the reception circuit information storage area of the storage unit 409 according to the flowchart of the grouping process illustrated in FIG. To remember. Hereinafter, group information and master sync receiving circuit specifying information are collectively referred to as receiving circuit information. The grouping process will be described in detail later. The receiving circuit information and the receiving circuit information storage area will be described later in detail with reference to FIG.

Further, as shown in FIG. 8B, the display control apparatus 400 is connected to three personal computers 500, 600, and 700 using six DVI cables. Specifically, the personal computer 500 has DVI signal output terminals 501 to 503. One end of each of the three DVI cables is connected to the three input terminals 1 to 3, and the other end is connected to the DVI signal output terminals 501 to 503. The personal computer 600 has DVI signal output terminals 601 and 602. One end of each of the two DVI cables is connected to the two input terminals 4 and 5, and the other end is connected to the DVI signal output terminals 601 and 602. The personal computer 700 has a DVI signal output terminal 701. One end of one DVI cable is connected to one input terminal 6, and the other end is connected to a DVI signal output terminal 701. The personal computer 500 has a function of outputting one image (high resolution image) signal by outputting an image signal (divided image signal) from each of the three DVI signal output terminals 501 to 503. The personal computer 600 has a function of outputting one image signal by outputting an image signal from each of the two DVI signal output terminals 601 and 602. The personal computer 700 has one DVI signal output terminal 701 and has a function of outputting one image signal.
In this embodiment, it is assumed that an output signal from each personal computer is input to the display control device 400 when the display control device 400 is activated.

  FIG. 9 is a diagram illustrating an example of the relationship between the system status and the state of the receiving circuit according to the second embodiment. In the display control apparatus according to the second embodiment, when one image signal representing one independent image is input to one input terminal, the image signals of a plurality of divided images obtained by dividing one image are displayed. It is possible to deal with both cases where the signals are input to a plurality of input terminals. In the example of FIG. 9, one image is input by three image signals input to the input terminals 1 to 3 (reception circuits 401 to 403). That is, a plurality of divided image signals obtained by dividing one image are input to the receiving circuits 401 to 403. In addition, two image signals input to the input terminals 4 and 5 (reception circuits 404 and 405) and an image signal input to the input terminal 6 (reception circuit 406) are respectively input to one image.

  The display image includes an image based on the image signal input to the reception circuits 401 to 403, an image based on the image signal input to the reception circuits 404 and 405, and an image based on the image signal input to the reception circuit 406. Can be switched between. Specifically, the receiving circuit used for display is in accordance with an instruction from the user from among group A consisting of receiving circuits 401 to 403, group B consisting of receiving circuits 404 and 405, and group C consisting of receiving circuit 406. Selected. That is, an external device that outputs an image signal used for display is selected from the connected external devices (PCs 500, 600, and 700) in accordance with an instruction from the user. In this embodiment, the control unit 408 selects one of the connected external devices as an external device that outputs an image signal used for display on the display unit in response to an instruction from the user. However, such a selection may be performed by another functional unit.

Reference numeral 1301 indicates the state of each receiving circuit when the system status is in the standby state. In a standby state (a state where no signal is received), it is possible to monitor the presence / absence of signals from each external device by monitoring only the master sync receiving circuit. Therefore, in this embodiment, when the system status is in the standby state, the driving power is supplied only to the master sync receiving circuits of all groups regardless of the selected state of the group (external device). In this way, power saving can be realized by not supplying drive power to unnecessary receiving circuits.
Reference numeral 1302 indicates the state of each receiving circuit when the system status is the power-on state and the group A is selected by an instruction from the user or the like. In this state, driving power is supplied to all the receiving circuits in the selected group A, and driving power is not supplied to all the receiving circuits in other groups. Reference numerals 1303 and 1304 indicate the states of the receiving circuits when the system status is the power-on state and the groups B and C are selected. In these states, as in the state 1302, the driving power is supplied to all the receiving circuits in the selected group, and the driving power is not supplied to all other receiving circuits.

  Although FIG. 9 shows an example in which all receiving circuits are grouped, there may be receiving circuits that are not grouped. In that case, when the system status is in the standby state, driving power may be supplied to the receiving circuits that are not grouped. For example, in FIG. 9, when only group A is grouped, when the system status is in the standby state, drive power is supplied only to the master sync receiving circuit of group A and the receiving circuits 404 to 406. That's fine. As a result, it is possible to receive a signal by a receiving circuit that is not grouped. Note that the drive power may be always supplied to the reception circuits that are not grouped regardless of the system status and the group selection state.

FIG. 10 is a diagram illustrating an example of the contents of the receiving circuit information storage area according to the second embodiment.
In the receiving circuit information storage area, receiving circuit information (group information and master sync receiving circuit specifying information) is stored for each receiving circuit.
The group information is information indicating a group of each receiving circuit, that is, information specifying an external device that outputs a signal received by each receiving circuit. The group information is information for classifying the receiving circuit according to the synchronization timing of the input image signal, the signal format, and the like. In this embodiment, the initial value of the group information is 0, and the numbers 1, 2, 3,... Are set as the group information in the order in which the image signals are received. In the example of FIG. 10, since the image signals are received in the order of groups A, B, and C, the group information of groups A, B, and C is 1, 2, and 3, respectively.
The master sync receiving circuit specifying information is information specifying the master sync receiving circuit. Specifically, the master sync receiving circuit specifying information of the receiving circuit that first receives the image signal in the group is “1” indicating that the receiving circuit is the master sync receiving circuit. The master sync receiving circuit specifying information of the receiving circuit that has received the second and subsequent image signals in the group is set to “0” indicating that the receiving circuit is not the master sync receiving circuit.
The flow of the receiving circuit information storing process (grouping process) will be described later in detail with reference to FIG.

FIG. 11 is a flowchart illustrating an example of a processing flow when the main power supply of the display control apparatus according to the second embodiment is turned on.
First, when the main power is turned on, the control unit 408 supplies driving power to each functional unit necessary for screen display (S1501), and sets the system status to the power-on state (S1502).
Next, the control unit 408 performs grouping processing (S1503), and then repeatedly performs reception monitoring processing (S1505) while the main power of the display control device is turned on (S1504).

FIG. 12 is a flowchart illustrating an example of the grouping process (S1503) according to the second embodiment. The grouping process is performed when a plurality of external devices are connected to the display control device and an external device that outputs a signal received by each receiving circuit is not specified. The grouping process is performed, for example, when the display main power is turned on (when a BIOS screen as shown in FIG. 2 is displayed) or when an image signal is received by a receiving circuit that is not grouped.
In this embodiment, the master sync receiving circuit is specified by the grouping process described below.

The control unit 408 registers reception circuit information (records in the reception circuit information storage area) for each reception circuit by the processing of S1603 to S1607 described below.
In step S1603, the control unit 408 checks whether an image signal is received by the receiving circuit to be processed.
When the image signal is received by the receiving circuit to be processed, the control unit 408 checks whether the receiving circuit information of the receiving circuit is already registered (S1604). When the image signal is not received by the processing target receiving circuit, the control unit 408 switches the processing target receiving circuit to the next receiving circuit, and performs the processing from S1603 (S1602).

  In S1604, if the receiving circuit information of the receiving circuit to be processed is not registered, or if information different from the receiving circuit information received in S1603 is registered as the receiving circuit information to be processed, the receiving circuit information is updated. Then, the control unit 408 performs the process of S1605. When information different from the reception circuit information received in S1603 is registered as the reception circuit information to be processed, the connection state between the display control apparatus 100 and the personal computer 200 when the reception circuit information is registered last time and the current time. May be different. Therefore, it is updated to the latest receiving circuit information. When the reception circuit information of the reception circuit to be processed has already been registered and the information is the same as the reception circuit information received in S1603, the control unit 408 switches the reception circuit to be processed to the next reception circuit, Processing from S1603 is performed.

  In step S <b> 1605, the control unit 408 receives an image signal having the same image signal information (synchronization timing and signal format) as the image signal received by the receiving circuit to be processed among the receiving circuits in which the receiving circuit information is already registered. Check whether there is a receiving circuit to receive.

  If there is no receiving circuit that receives image signals having the same image signal information, the control unit 408 determines that the external device that outputs a signal received by the receiving circuit to be processed is a newly specified external device. . Also, the control unit 408 determines that the receiving circuit to be processed is a master sync receiving circuit. Then, the control unit 408 registers reception circuit information representing a master sync reception circuit of a new group (a newly specified external device) as reception circuit information of the reception circuit to be processed (S1606). For example, when “2” is already registered as the group information, “3” is registered as the group information of the receiving circuit to be processed. Also, “1” is registered as master sync receiving circuit specifying information of the receiving circuit to be processed.

  When there is a receiving circuit that receives an image signal having the same image signal information, the control unit 408 outputs an image signal having the same image signal information from an external device that outputs a signal received by the receiving circuit to be processed. Judge that it is the same as the external device. In addition, the control unit 408 determines that the receiving circuit to be processed is not a master sync receiving circuit. Then, the control unit 408 receives, as reception circuit information of the reception circuit to be processed, reception circuit information indicating that the image signal information is the same group as the reception circuit that receives the same image signal and is not a master sync reception circuit. Is registered (S1607). Specifically, the same group information as that of the receiving circuit that receives the image signal having the same image signal information is registered as the group information of the receiving circuit to be processed. Further, “0” is registered as master sync receiving circuit specifying information of the receiving circuit to be processed.

Following the processing of S1607 and S1606, the control unit 408 switches the receiving circuit to be processed to the next receiving circuit, and performs the processing from S1603 (S1602). The loop process of S1602 may be repeated until reception circuit information of all reception circuits is registered, or may be repeated for a predetermined time (a predetermined number of times). In the example of FIG. 12, the processing is sequentially performed from the receiving circuit 401 corresponding to the input terminal 1 to the receiving circuit 406 corresponding to the input terminal 6. Thereafter, when the loop process of S1602 is performed, the receiving circuit 401 corresponding to the input terminal 1 is a processing target.

As described above, in the present exemplary embodiment, when a plurality of external devices are connected to the display control device and a reception circuit that receives a master sync signal output from each external device is not specified, all reception is performed. Driving power is supplied to the circuit. Then, for each connected external device, the reception circuit first detected by the reception detection unit 407 is identified as the reception circuit that receives the master sync signal output by the external device.
Further, in this embodiment, when a plurality of external devices are connected to the display control apparatus and no external device that outputs a signal received by each receiving circuit is specified, all the receiving circuits are connected. Drive power is supplied. And the external apparatus which outputs the signal received by each receiving circuit is specified from the image signal received by each receiving circuit.

The grouping process may be executed when a change in input terminal connected to an external device (that is, a change in group) is performed. The change of the group may be detected, for example, by detecting user operation (image display instruction) or connection of a cable to the input terminal. When a group change is detected, the system status is set to a power-on state (or a standby state in which driving power is supplied to some functional units including all receiving circuits), and the above grouping process is performed. Just do it.
In the present embodiment, the external device that outputs a signal received by each receiving circuit and the master sync receiving circuit are specified at the same time by the grouping process, but the specifying method is not limited to this. For example, after specifying an external device that outputs a signal received by each receiving circuit, a receiving circuit that receives a master sync signal of each external device may be specified.

FIG. 13 is a flowchart illustrating an example of the reception monitoring process (S1505) according to the second embodiment. This process is repeated while the main power is on after the grouping process.
First, the control unit 408 checks whether the system status is a power-on state (S1701).
If the system status is not in the power-on state in S1701 (that is, in the standby state), the control unit 408 sets the reception circuit to which the driving power is supplied as the processing target. Then, the control unit 408 checks for each receiving circuit to be processed whether or not a signal is received by the receiving circuit (S1702, S1703). Specifically, the presence / absence of signal reception is confirmed while switching the master sync receiving circuit of each group and the receiving circuit not grouped one by one. Whether or not a signal is received by the reception circuit is confirmed by monitoring the detection result of the reception circuit (the detection result of the reception detection unit 407) for a predetermined time.
If a receiving circuit receiving a signal is found during the loop processing in S1702, the control unit 408 starts supplying driving power to all receiving circuits in the same group as the receiving circuit (S1704). Then, the supply of drive power to the other receiving circuits (receiving circuits that do not belong to the group of receiving circuits confirmed to receive signals in S1703) is stopped (S1705). Then, the control unit 408 sets the system status to the power-on state (S1706) and ends the process. At this time, the control unit 408 selects the group for which the supply of drive power has been started in S1704. If the receiving circuit receiving the signal is an ungrouped receiving circuit, the grouping process (the process of FIG. 12) is performed, and then the process of S1704 is performed.
If no receiving circuit receiving a signal is found in the loop processing of S1702, the control unit 408 ends the processing.
Note that the loop processing of S1702 is repeated for a predetermined time (a predetermined number of times). For example, each receiving circuit to which driving power is supplied is set as the processing target of S1703 once.

  As described above, in this embodiment, the driving power is supplied only to the receiving circuit that receives the master sync signal output from each connected external device. Then, when reception of the master sync signal is detected by the reception detection unit 407, supply of drive power to other reception circuits that receive an image signal output from the external device that is the output source of the master sync signal is started. The

  When the system status is the power-on state in S1701, the control unit 408 checks whether or not a signal is received by the master sync reception circuit of the selected group (S1707). Whether or not a signal is received by the receiving circuit is confirmed by monitoring the receiving circuit for a predetermined time. If it is confirmed that the master sync receiver circuit of the selected group has received a signal, this flow is terminated. If reception of a signal at the master sync receiver circuit of the selected group is not confirmed, the control unit 408 supplies drive power to all the receiver circuits of the selected group other than the master sync receiver circuit. Is stopped (S1708). In addition, the control unit 408 starts supplying drive power to the master sync reception circuits of all groups and the reception circuits that are not grouped (S1709). Then, the control unit 408 sets the system status to the standby state (S1710) and ends the process.

As described above, according to the present embodiment, driving power is supplied only to the receiving circuit that receives the master sync signal output from each connected external device. Then, when reception of the master sync signal is detected by the reception detection unit 407, supply of drive power to other reception circuits that receive an image signal output from the external device that is the output source of the master sync signal is started. The As a result, even when multiple external devices are connected, it is possible to receive multiple image signals and display multiple images based on the multiple image signals on the display unit with low power consumption. It becomes. Specifically, the power consumption until a signal is received can be reduced as compared with the prior art.
Further, according to this embodiment, when reception of a signal at the master sync receiving circuit is no longer detected, driving power is supplied only to the receiving circuit that receives the master sync signal output from each connected external device. Then, driving power is not supplied to the other receiving circuits. Thereby, power consumption can be further reduced. Specifically, power consumption from when a signal is no longer received until the signal is received again can be reduced as compared with the prior art.

In the present embodiment, it is described on the assumption that the output signal from each personal computer is input when the display control device 400 is activated, but the signal is input after the display control device 400 is activated. Also good. Even in this case, it can be dealt with by performing a grouping process.
In this embodiment, the group for which the supply of drive power is started in S1704 is selected. However, the group may be selected according to an instruction from the user. In that case, in S1703, it may be confirmed whether or not a signal is received by the master sync receiving circuit corresponding to the selected external device. For this reason, in the standby state, it is sufficient that at least the driving power is supplied to the master sync receiving circuit corresponding to the selected external device.

100, 400 Display control device 101-104, 401-406 Reception circuit 105, 407 Reception detection unit 106, 408 Control unit

Claims (8)

A display control device capable of receiving a plurality of image signals from a connected external device and displaying a plurality of images based on the plurality of image signals on a display unit,
A plurality of receiving circuits for receiving a plurality of image signals;
Detection means for detecting reception of a signal in each receiving circuit;
Control means for controlling supply / non-supply of drive power of each receiving circuit;
Have
The external device outputs a plurality of image signals from a plurality of output terminals after outputting a master sync signal from one output terminal at startup,
The control means includes
Supply drive power only to the receiving circuit that receives the master sync signal,
A display control apparatus, characterized in that, when reception of a master sync signal is detected by the detecting means, supply of driving power to another receiving circuit is started. The control means stops supply of driving power to the other receiving circuit when reception of a signal in the receiving circuit that receives a master sync signal is no longer detected by the detecting means. The display control apparatus according to 1. When the receiving circuit that receives the master sync signal is not specified,
The control means includes
Supply driving power to all receiving circuits,
3. The display control apparatus according to claim 1, wherein a reception circuit in which reception of a signal is first detected by the detection unit is specified as a reception circuit that receives a master sync signal. A plurality of external devices can be connected to the display control device,
The control means includes
Supply drive power only to the receiver circuit that receives the master sync signal output from each connected external device,
When reception of a master sync signal is detected by the detection means, supply of drive power to another receiving circuit that receives an image signal output from an external device that is an output source of the master sync signal is started. The display control apparatus according to any one of claims 1 to 3. When a plurality of external devices are connected to the display control device and a receiving circuit for receiving a master sync signal output from each external device is not specified,
The control means includes
Supply driving power to all receiving circuits,
The reception circuit in which reception of a signal is first detected by the detection unit is identified as a reception circuit that receives a master sync signal output from the external device for each connected external device. 5. The display control device according to 4. When a plurality of external devices are connected to the display control device and an external device that outputs a signal received by each receiving circuit is not specified,
The control means includes
Supply driving power to all receiving circuits,
6. The display control apparatus according to claim 4, wherein an external device that outputs a signal received by each receiving circuit is specified from an image signal received by each receiving circuit. The display control according to claim 1, wherein the plurality of image signals output from the external device are signals of a plurality of divided images obtained by dividing one image. apparatus. A control method for a display control apparatus capable of receiving a plurality of image signals from a connected external device and displaying a plurality of images based on the plurality of image signals on a display unit,
A receiving step of receiving a plurality of image signals by a plurality of receiving circuits;
A detection step of detecting reception of a signal at each receiving circuit;
A control step for controlling supply / non-supply of drive power of each receiving circuit;
Have
The external device outputs a plurality of image signals from a plurality of output terminals after outputting a master sync signal from one output terminal at startup,
In the control step,
Supply drive power only to the receiving circuit that receives the master sync signal,
A control method for a display control apparatus, comprising: starting supply of drive power to another receiving circuit when reception of a master sync signal is detected in the detection step.

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