JP2013157850A - Stereoscopic video display devices, spectacles, synchronization method and stereoscopic image system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide stereoscopic video display devices allowing for stereoscopic vision with any spectacles in viewing the stereoscopic video display devices displaying different contents.SOLUTION: A stereoscopic video display device comprises: a synchronization unit which determines a display timing of a right-eye video and a left-eye video of video data to be displayed on a display unit and generates from the display timing a synchronization signal for synchronizing another stereoscopic video display device with at least one pair of spectacles worn by a user in viewing a stereoscopic video; a display control unit which causes the right-eye video and the left-eye video of the video data to be displayed on the display unit on the basis of the display timing; and a transmission unit which transmits a synchronization signal generated by the synchronization unit to the another stereoscopic video display device and the spectacles.

Description

  The present disclosure relates to a stereoscopic video display device capable of displaying a three-dimensional image, glasses for stereoscopic video viewing, a synchronization method thereof, and a stereoscopic image system.

  2. Description of the Related Art In recent years, display devices such as 3D displays that can display a stereoscopic image in which a subject has a sense of depth in depth and width information are displayed as display devices that display images of television programs, movies, games, and the like. It's getting on. Three-dimensional images enable the expression of reality and realism by allowing viewers to recognize depth and three-dimensionality using a mechanism in which humans see objects with both eyes.

  As a 3D image display apparatus for displaying a 3D image, there are a frame sequential system, a naked eye system, a passive system, and the like. Among them, in the frame sequential method, the right eye image and the left eye image are alternately displayed on the display device side, and in accordance with each display timing, glasses for viewing a three-dimensional image with a synchronization signal are displayed. Controls the opening and closing timing of the right-eye shutter and the left-eye shutter. In this way, the images corresponding to the right eye and the left eye are respectively shown, and this is repeated at high speed to make the brain perceive as a three-dimensional image.

JP 2003-168136 A

  In order to enable stereoscopic viewing by the frame sequential method, the display timing of the image on the display device and the opening / closing timing of the shutter of the glasses must be synchronized. If this adjustment is shifted, the user feels uncomfortable with the video. For this reason, glasses can usually be synchronized with only one display device, and a three-dimensional image displayed on another display device cannot be viewed with the same glasses.

  For example, Patent Document 1 discloses a stereoscopic image system in which the same three-dimensional image content displayed on a plurality of display devices can be viewed with the same glasses. However, since this stereoscopic image system assumes that the content displayed on each display device is the same, it cannot be applied when the content is different. For this reason, it is desired that a stereoscopic video display device displaying different contents can be stereoscopically viewed with any glasses.

  According to the present disclosure, the display timing of the right-eye video and the left-eye video of the video data to be displayed on the display unit is determined, and the user wears when viewing another stereoscopic video display device and the stereoscopic video from the display timing. Generated by a synchronization unit that generates a synchronization signal that synchronizes at least one pair of glasses, a display control unit that displays a right-eye image and a left-eye image of video data on a display unit based on display timing, and a synchronization unit A stereoscopic video display device comprising: a transmission unit that transmits the synchronization signal to another stereoscopic video display device and glasses.

  In addition, according to the present disclosure, the synchronization signal that synchronizes the stereoscopic video display device capable of displaying stereoscopic video and the shutter-type glasses worn by the user when viewing the stereoscopic video displayed by each stereoscopic video display device. A spectacle is provided that includes a receiving unit that receives a synchronization signal from the main device that generates the shutter, and a shutter control unit that controls the opening and closing timings of the right-eye shutter and the left-eye shutter based on the synchronization signal.

  Further, according to the present disclosure, a plurality of stereoscopic video display devices capable of displaying a stereoscopic video, at least one shutter-type glasses worn by a user when viewing the stereoscopic video displayed by each stereoscopic video display device, Generating a synchronization signal for synchronizing the stereoscopic image display device and the glasses, transmitting the generated synchronization signal to another stereoscopic image display device and the glasses, and receiving by at least one of Performing a display control of each stereoscopic video display device and a shutter control of glasses based on the synchronization signal thus obtained is provided.

  In addition, according to the present disclosure, a plurality of stereoscopic video display devices capable of displaying a stereoscopic video, at least one shutter-type glasses worn by a user when viewing the stereoscopic video displayed by each stereoscopic video display device, And at least one of the stereoscopic video display device and the glasses includes a synchronization unit that generates a synchronization signal for synchronizing the stereoscopic video display device and the glasses, and the synchronization signal as another stereoscopic video display device and glasses. A stereoscopic image system comprising: a transmission unit configured to transmit to

  As described above, according to the present disclosure, a stereoscopic image display device displaying different contents can be stereoscopically viewed with any glasses.

1 is a system configuration diagram illustrating a configuration of a stereoscopic image system according to a first embodiment of the present disclosure. It is a block diagram which shows one structural example of a stereoscopic video display apparatus provided with a transmission part. It is a block diagram which shows the example of 1 structure of the stereo image display apparatus without a transmission part. It is a block diagram which shows the example of 1 structure of the glasses without a transmitter. It is a flowchart which shows the synchronous process of the stereo image display apparatus which can become the main apparatus which concerns on the embodiment. It is a flowchart which shows the synchronous process of the three-dimensional video display apparatus which does not have the synchronizing signal transmission function which concerns on the same embodiment. FIG. 3 is an explanatory diagram illustrating a specific configuration example of a stereoscopic image system according to the embodiment. FIG. 8 is an explanatory diagram showing switching of main devices in the stereoscopic image system shown in FIG. 7. It is explanatory drawing which shows the structure of the stereo image system which concerns on 2nd Embodiment of this indication. It is a block diagram which shows the structure of the glasses which function as a main apparatus. It is a system configuration diagram showing a case where a main device and other devices communicate one-to-many in a stereoscopic image system. It is a system block diagram which shows the case where each apparatus which comprises a stereo image system communicates many-to-many. It is a flowchart which shows the setting process of a main flag. It is a flowchart which shows the process in the case of performing the process of FIG. 5 using a main flag. It is explanatory drawing for demonstrating the process which determines a main apparatus based on the number of glasses in the circumference | surroundings of a three-dimensional video display apparatus. It is a flowchart which shows the process which determines a main apparatus based on the number of glasses in the circumference | surroundings of a three-dimensional video display apparatus. It is explanatory drawing for demonstrating the process which determines the 3D image display apparatus nearest to the 3D image display apparatus which was functioning as the main apparatus to a main apparatus. It is explanatory drawing for demonstrating the process which determines the spectacles nearest to the spectacles which were functioning as a main apparatus to a main apparatus. It is a flowchart which shows the process which determines a main apparatus based on the distance with the apparatus which was functioning as a main apparatus. It is explanatory drawing for demonstrating the process determined to a main apparatus based on a priority. It is explanatory drawing for demonstrating the process determined to a main apparatus based on a priority, when the power supply of the main apparatus of FIG. 20 is turned off. It is a flowchart which shows the process which determines a main apparatus based on a priority.

  Hereinafter, preferred embodiments of the present disclosure will be described in detail with reference to the accompanying drawings. In addition, in this specification and drawing, about the component which has the substantially same function structure, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol.

The description will be made in the following order.
1. First Embodiment 1-1. Stereoscopic image system configuration (stereoscopic image system, stereoscopic image display device, glasses)
1-2. Stereo image system synchronization processing (synchronization processing of a stereoscopic video display device that can be a main device, synchronization processing of a stereoscopic video display device that operates based on a synchronization signal from the main device, application example)
2. Second embodiment 3. 3. Communication in a stereoscopic image system Determination of main equipment 4-1. Main device determination process 4-2. Main device determination processing (determination of the main device based on the number of glasses around the stereoscopic image display device, determination of the main device based on the distance from the device functioning as the main device, determination of the main device based on the priority)

<1. First Embodiment>
[1-1. Stereoscopic image system configuration]
First, the configuration of the stereoscopic image system 1 according to the first embodiment of the present disclosure will be described with reference to FIGS. FIG. 1 is a system configuration diagram showing the configuration of the stereoscopic image system 1 according to the present embodiment. FIG. 2 is a block diagram illustrating a configuration example of the stereoscopic video display device 100 including the transmission unit 150. FIG. 3 is a block diagram illustrating a configuration example of the stereoscopic video display apparatus 100 without a transmission unit. FIG. 4 is a block diagram illustrating a configuration example of the glasses 200 without a transmitter.

(Stereoscopic image system)
The stereoscopic image system 1 includes a plurality of stereoscopic video display devices 100 capable of displaying a three-dimensional image and at least one pair of glasses 200. For example, as shown in FIG. 1, a plurality of stereoscopic video display devices 100A to 100E The plurality of glasses (glasses) 200A to 200C. The numbers of the stereoscopic video display device 100 and the glasses 200 constituting the stereoscopic image system 1 are not limited to such an example. Each device constituting the stereoscopic image system 1 can communicate with at least a main device that outputs a synchronization signal. The communication may be wireless communication using a wireless LAN (Local Area Network), a wireless USB, or the like, or may be wired communication using a cable connection or the like.

  The stereoscopic video display device 100 is an output device that displays a three-dimensional image at a display timing determined based on a synchronization signal on a display unit. Each stereoscopic video display device 100 constituting the stereoscopic image system 1 of the present embodiment can display the same content, and can also display different content. In the glasses 200 for stereoscopically viewing the three-dimensional image displayed on the stereoscopic video display device 100, the shutter is opened and closed at an opening and closing timing determined based on the synchronization signal.

  Any one of the stereoscopic video display device 100 and the glasses 200 constituting the stereoscopic image system 1 generates a synchronization signal that determines the image display timing and the shutter opening / closing timing of the glasses 200 in the stereoscopic video display device 100, Send to each device. Hereinafter, the stereoscopic video display device 100 or the glasses 200 that generate and transmit a synchronization signal is referred to as a main device. For example, in the example illustrated in FIG. 1, the stereoscopic video display device 100 </ b> A functions as the main device. Other stereoscopic video display devices 100B to 100E and glasses 200A to 200C operate by determining display timing or opening / closing timing based on a synchronization signal transmitted from the main device.

  Thus, in the stereoscopic image system 1, there is one main device that can generate and transmit a synchronization signal, and other devices operate based on the synchronization signal transmitted from the main device. Thereby, even if it sees the three-dimensional image which which stereoscopic image display apparatus 100A-100E displays with which glasses 200A-200C, a three-dimensional image can be stereoscopically viewed without a sense of incongruity.

(3D image display device)
The configuration of the stereoscopic video display device 100 will be described in detail. First, the stereoscopic video display device 100 capable of generating and transmitting a synchronization signal includes a receiving unit 110 and a synchronization signal control / generation unit 120 as shown in FIG. A display control unit 130, a display unit 140, and a transmission unit 150. The stereoscopic video display device 100 that can generate and transmit a synchronization signal is a device that can function as a main device.

  The receiving unit 110 receives a synchronization signal that determines the display timing for displaying the right-eye video and the left-eye video. When receiving the synchronization signal, the reception unit 110 outputs the synchronization signal to the synchronization signal control / generation unit 120.

  The synchronization signal control / generation unit 120 determines the display timing for displaying the right-eye video and the left-eye video based on the synchronization signal. When the synchronization signal is received by the reception unit 110, the synchronization signal control / generation unit 120 determines the display timing based on the received synchronization signal and outputs the display timing to the display control unit 130. Further, when the synchronization signal control / generation unit 120 detects that the synchronization signal is not received by the reception unit 110, the synchronization signal control / generation unit 120 generates a synchronization signal and outputs the display timing determined based on the generated synchronization signal to the display control unit 130. At the same time, the synchronization signal is output to the transmission unit 150.

  The display control unit 130 displays the input video data at the display timing determined by the synchronization signal control / generation unit 120. The input video data is video data read from an external input or internal storage, and is input video data at the timing of a right eye frame or a left eye frame (video) displayed on the display unit 140 by the display control unit 130. Display control.

  The display unit 140 is one of output units that display input video data. For example, a liquid crystal display, an organic EL display, or the like can be used. The display unit 140 alternately displays the right-eye video and the left-eye video of the input video data controlled by the display control unit 130 so as to be displayed based on the display timing.

  The transmission unit 150 transmits the synchronization signal generated by the synchronization signal control / generation unit 120 to other devices constituting the stereoscopic image system 1.

  On the other hand, some stereoscopic video display devices 100 cannot transmit a synchronization signal, and have a configuration as shown in FIG. 3, for example. That is, such a stereoscopic video display device 100 includes a receiving unit 110, a display control unit 130, and a display unit 140. In the stereoscopic video display device 100, the display control unit 130 causes the display unit 140 to display the input video data at the same timing based on the synchronization signal received by the reception unit 110. Except that the synchronization signal control / generation unit 120 and the transmission unit 150 are not provided, it functions in the same manner as the stereoscopic video display device 100 shown in FIG. Thus, the stereoscopic video display apparatus 100 that does not include the transmission unit 150 for transmitting the synchronization signal cannot function as a main device.

(Glasses)
The glasses 200 for viewing the three-dimensional image displayed by the stereoscopic video display device 100 have a configuration as shown in FIG. 4, for example. That is, the glasses 200 include a receiving unit 210, a shutter control unit 220, a right eye shutter 230, and a left eye shutter 240.

  The receiving unit 210 receives a synchronization signal transmitted from the main device, which is used to determine the opening / closing timing of the right-eye shutter 230 and the left-eye shutter 240. The receiving unit 210 outputs the received synchronization signal to the shutter control unit 220.

  The shutter control unit 330 controls the opening / closing of the right-eye shutter 230 and the left-eye shutter 240 at the opening / closing timing based on the synchronization signal. Accordingly, when the right-eye video is displayed on the stereoscopic video display device 100, the right-eye shutter 230 is opened and the left-eye shutter 240 is closed. When the left-eye video is displayed on the stereoscopic video display device 100, the left-eye shutter 240 is opened and the right-eye shutter 230 is closed.

  As will be described later, the glasses 200 can also have a function of generating and transmitting a synchronization signal. In this case, the glasses 200 can also function as a main device of the stereoscopic image system 1.

[1-2. Stereo image system synchronization processing]
Hereinafter, based on FIGS. 5 to 8, synchronization processing of each device constituting the stereoscopic image system 1 according to the present embodiment will be described. FIG. 5 is a flowchart showing the synchronization processing of the stereoscopic video display apparatus 100 that can be the main device according to the present embodiment. FIG. 6 is a flowchart showing a synchronization process of the stereoscopic video display apparatus 100 that does not have the synchronization signal transmission function according to the present embodiment. 7 and 8 are explanatory diagrams illustrating a specific configuration example of the stereoscopic image system 1 according to the present embodiment.

(Synchronization processing of stereoscopic video display device that can be the main device)
First, based on FIG. 5, the synchronization process of the stereoscopic video display apparatus 100 that can be the main device will be described. That is, FIG. 5 shows a synchronization process of the stereoscopic video display apparatus 100 having the configuration shown in FIG.

  First, the stereoscopic video display apparatus 100 tries to receive a synchronization signal by the receiving unit 110 (S100). Then, the synchronization signal control / generation unit 120 confirms whether or not the synchronization signal can be received from another device in step 100 (S101). That is, in step S101, the stereoscopic video display apparatus 100 confirms whether or not a device that functions as a main device already exists in the stereoscopic image system 1 to which the stereoscopic video display device 100 belongs.

  When it is determined in step S101 that the synchronization signal cannot be received, the synchronization signal control / generation unit 120 generates a synchronization signal for synchronizing the stereoscopic image system 1 and outputs the synchronization signal to another device via the transmission unit 150. (S102). That is, the stereoscopic video display device 100 functions as a main device of the stereoscopic image system 1. At this time, the synchronization signal control / generation unit 120 determines a display timing for displaying the input video data based on the generated synchronization signal, and outputs the display timing to the display control unit 130. On the other hand, if it is determined in step S101 that the synchronization signal can be received, the synchronization signal control / generation unit 120 determines the display timing for displaying the input video data based on the received synchronization signal, and the display control unit 130 Output to.

  Thereafter, the display control unit 130 causes the display unit 140 to alternately display the right-eye video and the left-eye video of the input image data based on the determined display timing, so that the display control unit 130 and the other devices of the stereoscopic image system 1 are displayed. Are synchronized (S103). In this way, a stereoscopic image is displayed on the display unit 140 (S104). The processes in steps S100 to S104 are repeated until the display of the input video data by the stereoscopic video display device 100 is completed (S105). The repeated interval may be, for example, every predetermined time (for example, 10 seconds). When the scene of the video data being played changes (for example, when it becomes darker to brighter, or the chapter boundaries set in the video data). Or a time interval specified by the user. Alternatively, it may be when the number of connected stereoscopic video display devices or glasses changes, or when the distance between the connected stereoscopic video display device and glasses is large (for example, 50% or more of the original distance), It may be when the priority setting described later is changed. This also applies to the repeated processing described below.

(Synchronization processing of a stereoscopic display device that operates based on a synchronization signal from the main device)
Next, based on FIG. 6, a synchronization process of the stereoscopic video display apparatus 100 that operates based on a synchronization signal from the main device will be described. That is, FIG. 6 shows the synchronization processing of the stereoscopic video display apparatus 100 having a configuration that does not include the synchronization signal control / generation unit 120 and the transmission unit 150 as shown in FIG.

  First, the stereoscopic image display apparatus 100 attempts to receive a synchronization signal by the receiving unit 110 (S110). In step 110, it is confirmed whether or not a synchronization signal can be received from another device (S111). The stereoscopic video display apparatus 100 that cannot generate a synchronization signal functions in synchronization with other devices constituting the stereoscopic image system 1 by always receiving the synchronization signal.

  If it is determined in step S111 that the synchronization signal can be received, the display control unit 130 displays the input image data for the right eye and the left eye at the display timing for displaying the input video data based on the received synchronization signal. Images are alternately displayed on the display unit 140. Thereby, it synchronizes with the other apparatus of the stereoscopic image system 1 (S112), and displays the stereoscopic video on the display unit 140 (S113). The processes of steps S110 to S113 are repeated until the display of the input video data by the stereoscopic video display device 100 is completed (S114).

  On the other hand, when it is determined that the synchronization signal cannot be received, the display control unit 130 causes the display unit 140 to display the stereoscopic video data at a predetermined display timing set in advance, for example. In this case, there is a possibility that synchronization with other devices constituting the stereoscopic image system 1 is not achieved. However, when the stereoscopic video data is continuously displayed (S114), the processing of steps S110 to S113 is repeated. If synchronization signals can be received from the main device, synchronization can be achieved.

  In the present embodiment, the glasses 200 operate based on a synchronization signal from the main device. Therefore, similar to the synchronization processing of the stereoscopic video display apparatus 100 shown in FIG. 6, the shutter control unit 220 controls the opening and closing of the right-eye shutter 230 and the left-eye shutter 240 based on the synchronization signal from the main device. Do. When the synchronization signal cannot be received, for example, the opening / closing control of each shutter 230, 240 may be performed at a preset opening / closing timing, and each shutter 230, 240 is received until the synchronization signal can be received from the main device. May not be opened. When the reception unit 210 of the glasses 200 continues to receive the synchronization signal, the glasses 200 can be operated in synchronization with other devices of the stereoscopic image system 1 when the synchronization signal can be received. it can.

(Application example)
7 and 8 show a specific configuration example of the stereoscopic image system 1 shown in FIG. As shown in FIG. 7, the stereoscopic image system 1 includes a 3D television (100A), a 3D display PC1 (100B), a 3D display PC2 (100C), and a 3D projector (100D) as a stereoscopic video display device 100. It consists of glasses 200A-200C. Among these, the 3D television (100A), the 3D display PC1 (100B), and the 3D display PC2 (100C) can generate and transmit a synchronization signal, and can function as a main device.

  One of the devices 100A to 100D and 200A to 200C constituting the stereoscopic image system 1 functions as a main device, and generates and transmits a synchronization signal for synchronizing the system. The main device can be, for example, the first activated device among devices that can function as the main device. In the example shown in FIG. 7, the 3D television (100A) functions as a main device to generate and transmit a synchronization signal. The other devices 100B to 100D and 200A to 200C receive the synchronization signal transmitted by the 3D television (100A) and operate at the display timing or the opening / closing timing determined based on the synchronization signal.

  When the power of the 3D television (100A) functioning as the main device in FIG. 7 is turned off, the 3D television (100A) cannot generate and transmit a synchronization signal. That is, there is no main device in the stereoscopic image system 1. In this case, other devices that can become the main device among the devices belonging to the stereoscopic image system 1 function as new main devices. The new main device can be determined, for example, from among other devices that can become the main device, the device that first transmitted the synchronization signal. The main determination method described later can also be applied. In the stereoscopic image system 1 shown in FIG. 7, when the 3D display PC 2 (100C) first generates a synchronization signal, the 3D display PC 2 (100C) functions as a new main device as shown in FIG. As a result, other devices operate based on the synchronization signal generated by the 3D display PC 2 (100C), and the devices constituting the stereoscopic image system 1 can be continuously synchronized.

  Heretofore, the configuration of the stereoscopic image system 1 according to the first embodiment and the synchronization processing of each device configuring the system have been described. According to the present embodiment, one of the devices belonging to the stereoscopic image system 1 that can generate and transmit a synchronization signal is set as the main device, and the other devices are based on the synchronization signal transmitted from the main device. Determines the display timing or opening / closing timing. Accordingly, each stereoscopic image display device 100 displays the right-eye video and the left-eye video at the same display timing regardless of the three-dimensional image to be displayed, and the glasses 200 display the right eye at the opening / closing timing corresponding to the display timing. The shutter 230 for the eye and the shutter 240 for the left eye are opened and closed. Accordingly, it is possible to view a stereoscopic video by viewing which stereoscopic video display device 100 image with which glasses 200.

<2. Second Embodiment>
Next, the stereoscopic image system 1 according to the second embodiment of the present disclosure will be described based on FIGS. 9 and 10. In addition, FIG. 9 is explanatory drawing which shows the structure of the stereo image system 1 which concerns on this embodiment. FIG. 10 is a block diagram illustrating a configuration of glasses 200 that function as a main device.

  In the stereoscopic image system 1 according to the present embodiment, the glasses 200 function as a main device. That is, as shown in FIG. 9, in the stereoscopic image system 1 including, for example, a plurality of stereoscopic video display devices 100A to 100E and glasses 200A to 200C, the glasses 1 (200A) function as a main device.

  At this time, the glasses 200 that can be the main device need to be able to generate and transmit a synchronization signal, like the stereoscopic image display device 100 that can be the main device. Such glasses 200 include, for example, a synchronization signal control / generation unit 250 in addition to a reception unit 210, a shutter control unit 220, a right-eye shutter 230, and a left-eye shutter 240, as shown in FIG. A transmission unit 260. The receiving unit 210, the shutter control unit 220, the right-eye shutter 230, and the left-eye shutter 240 can have the same configuration and the same function as the glasses 200 in the first embodiment illustrated in FIG.

  The synchronization signal control / generation unit 250 determines an opening / closing timing for opening / closing the right-eye shutter 230 and the left-eye shutter 240 based on the synchronization signal. When the synchronization signal is received by the reception unit 210, the synchronization signal control / generation unit 250 determines the opening / closing timing based on the received synchronization signal and outputs it to the shutter control unit 220. In addition, when the synchronization signal control / generation unit 250 detects that the synchronization signal is not received by the reception unit 210, the synchronization signal control / generation unit 250 generates a synchronization signal and outputs the opening / closing timing determined based on the generated synchronization signal to the shutter control unit 220. At the same time, the synchronization signal is output to the transmitter 260.

  The transmission unit 260 transmits the synchronization signal generated by the synchronization signal control / generation unit 250 to other devices constituting the stereoscopic image system 1.

  Such glasses 200 function in the same manner as the synchronization processing of the stereoscopic video display apparatus 100 that can be the main in FIG. 5 described in the first embodiment. That is, the glasses 200 first try to receive the synchronization signal by the receiving unit 210. Then, the synchronization signal control / generation unit 250 confirms whether the synchronization signal can be received from another device. Here, the glasses 200 confirm whether or not a device that functions as a main device already exists in the stereoscopic image system 1 to which the glasses 200 belong.

  When the reception unit 210 determines that the synchronization signal cannot be received, the synchronization signal control / generation unit 250 generates a synchronization signal for synchronizing the stereoscopic image system 1 and sends it to another device via the transmission unit 260. Output. That is, the glasses 200 function as the main device of the stereoscopic image system 1. At this time, the synchronization signal control / generation unit 250 determines the opening / closing timings of the shutters 230 and 240 based on the generated synchronization signal, and outputs them to the shutter control unit 220. On the other hand, when the receiving unit 210 determines that the synchronization signal can be received, the synchronization signal control / generation unit 250 determines the opening / closing timing of the shutters 230 and 240 based on the received synchronization signal, and the shutter control unit To 220.

  Thereafter, based on the determined opening / closing timing, the shutter control unit 220 alternately opens / closes the right-eye shutter 230 and the left-eye shutter 240 to synchronize with other devices of the stereoscopic image system 1. In this way, the stereoscopic video displayed on the stereoscopic video display device 100 can be viewed. These processes are repeated until the use of the glasses 200 ends.

  As above, the configuration of the stereoscopic image system 1 according to the second embodiment and the synchronization processing of each device configuring the system have been described. According to the present embodiment, among the devices belonging to the stereoscopic image system 1, glasses 200, which is one of devices that can generate and transmit a synchronization signal, are used as the main device, and based on the synchronization signal transmitted from the main device. The other devices determine the display timing or the opening / closing timing. Accordingly, each stereoscopic image display device 100 displays the right-eye video and the left-eye video at the same display timing regardless of the three-dimensional image to be displayed, and the glasses 200 display the right eye at the opening / closing timing corresponding to the display timing. The shutter 230 for the eye and the shutter 240 for the left eye are opened and closed. Accordingly, it is possible to view a stereoscopic video by viewing which stereoscopic video display device 100 image with which glasses 200.

<3. Communication in stereoscopic image system>
In the above embodiment, each device configuring the stereoscopic image system 1 is configured to be able to receive a synchronization signal from at least a main device that transmits a synchronization signal, but the present technology is not limited to such an example. For example, as illustrated in FIG. 11, each device configuring the stereoscopic image system 1 may be able to communicate bidirectionally with the main device. That is, the stereoscopic video display device 100A as the main device and other devices (stereoscopic video display devices 1 to 4 (100B to 100E) and glasses 1 to 3 (200A to 200C)) can transmit and receive signals. Good (one-to-many communication). Thereby, for example, the main device can receive a response signal regarding whether or not the synchronization signal can be received from another device, and can adjust the strength of the synchronization signal based on the response signal.

  Alternatively, as illustrated in FIG. 12, communication may be performed between devices other than the main device configuring the stereoscopic image system 1 (many-to-many communication). Thereby, even if the device belonging to the stereoscopic image system 1 cannot receive the synchronization signal directly from the main device, the device of the stereoscopic image system 1 can be synchronized by enabling the synchronization signal to be received from the communicable device. it can.

  For example, the stereoscopic video display device 1 (100B) and the glasses 1 (200A) directly receive the synchronization signal from the stereoscopic video display device (100A) that is the main device, and determine the display timing or the opening / closing timing. On the other hand, the stereoscopic video display devices 2 to 4 (100C to 100E) and the glasses 2 and 3 (200B and 200C) that cannot directly communicate with the main device receive the synchronization signal from other devices that can communicate, and display timing or open / close Determine timing. As described above, if it is possible to communicate with at least one device in the stereoscopic image system 1, it is possible to receive the synchronization signal and operate in synchronization with other devices in the system 1. Furthermore, when the synchronization signal cannot be received from the main device or a device other than the main device, the synchronization signal may be generated and transmitted when the device can function as the main device.

<4. Determination of main equipment>
[4-1. Main device judgment process]
As described in the above embodiment, a device that can generate and transmit a synchronization signal can function as a main device. At this time, it is conceivable to use a main flag as a method for determining whether or not the device itself is a main device. The main flag is information used to determine whether or not the device is the main device. For example, when the device is the main device, the main flag is set to “1”, and when the device is not the main device, the main flag is set. Set “0” to the flag.

  The setting of the main flag is performed based on the process shown in FIG. 13, for example. First, the stereoscopic image display apparatus 100 or the glasses 200 determines whether or not a condition that can be a main device is satisfied (S200). The condition that can be the main device can be, for example, whether or not a synchronization signal can be received from another device, that is, whether or not there is already a device that functions as the main device. Specifically, it can be determined by whether or not the synchronization signal is received by the receiving unit 110 (or 210).

  When the synchronization signal is not received in step S200, it is determined that the device itself functions as a main device, and “1” is set to the main flag (S201). On the other hand, when the synchronization signal is received in step S200, the device itself does not function as the main device, and thus “0” is set to the main flag (S202). When a value is set in the main flag in step S201 or S202, it is determined whether or not to end the operation (S203), and the processes in steps S200 to S202 are repeated while the operation continues.

  By using the main flag, the synchronization processing of the stereoscopic video display apparatus 100 of FIG. 5 described in the first embodiment can be performed as shown in FIG. That is, the stereoscopic video display apparatus 100 first attempts to receive a synchronization signal by the receiving unit 110 (S210). Then, in step 210, the synchronization signal control / generation unit 120 checks whether or not the main flag is “1” (S211). That is, in step S211, the stereoscopic video display apparatus 100 confirms whether or not itself is the main device.

  When the main flag is “1”, the device itself functions as a main device. Therefore, the synchronization signal control / generation unit 120 generates a synchronization signal for synchronizing the stereoscopic image system 1 and outputs the synchronization signal to another device via the transmission unit 150 (S212). At this time, the synchronization signal control / generation unit 120 determines a display timing for displaying the input video data based on the generated synchronization signal, and outputs the display timing to the display control unit 130. On the other hand, when the main flag is not “1” (that is, “0”), the synchronization signal control / generation unit 120 displays the input video data based on the received synchronization signal because it is not the main device. The display timing to be determined is determined and output to the display control unit 130.

  Thereafter, the display control unit 130 causes the display unit 140 to alternately display the right-eye video and the left-eye video of the input image data based on the determined display timing, so that the display control unit 130 and the other devices of the stereoscopic image system 1 are displayed. Are synchronized (S213). In this way, a stereoscopic image is displayed on the display unit 140 (S214). The processes of steps S210 to S214 are repeated until the display of the input video data by the stereoscopic video display device 100 is completed (S215).

[4-2. Main device decision processing]
When there are a plurality of devices that can function as the main device in the stereoscopic image system 1, for example, the main device based on the number of glasses around the stereoscopic video display device, the distance from the device functioning as the main device, the priority, and the like. Can be determined. The main device determination process will be described below.

(Determination of the main device based on the number of glasses around the 3D image display device)
First, based on FIG. 15 and FIG. 16, a case where the main device is determined based on the number of glasses around the stereoscopic image display device 100 will be described. FIG. 15 is an explanatory diagram for describing processing for determining the main device based on the number of glasses around the stereoscopic video display device 100. FIG. 16 is a flowchart illustrating processing for determining a main device based on the number of glasses around the stereoscopic video display device 100.

  When the number of glasses around the stereoscopic video display device 100 is large, it is considered that the stereoscopic video displayed by the stereoscopic video display device 100 is viewed by many users. Such a stereoscopic image display apparatus 100 is also unlikely to be powered off. Therefore, it is conceivable that the stereoscopic video display device 100 having the largest number of glasses around the stereoscopic video display device 100 is determined as the main device.

  For example, as shown in FIG. 15, there are a 3D television (100A), a 3D display PC1 (100B), a 3D display PC2 (100C), and a 3D projector (100D) as the stereoscopic video display device 100 constituting the stereoscopic image system 1. And At this time, the 3D television (100A) and the 3D display PC1 (100B) communicate with only the glasses 1 (200A), and the 3D display PC2 (100C) communicates with the glasses 1 to 3 (200A to 200C). Further, the 3D projector (100D) communicates only with the glasses 3 (200C). Accordingly, the 3D display PC 2 (100C) that is considered to receive the most attention is determined as the main device. In this case, as shown in FIG. 12, it is assumed that each device constituting the stereoscopic image system 1 can perform many-to-many communication.

  Specifically, as shown in FIG. 16, first, each stereoscopic video display device 100 constituting the stereoscopic image system 1 counts the number of glasses 200 that are its communication counterpart device, and other stereoscopic video display devices. 100 (S220). The number of glasses can be counted by, for example, the number of glasses 200 that responds to a predetermined signal output from the stereoscopic video display device 100. This number is assumed to be Nn (n is a number for identifying the stereoscopic video display device 100).

  For example, the number of glasses around the 3D television (100A), the 3D display PC1 (100B), the 3D display PC2 (100C), and the 3D projector (100D) in FIG. 15 is N1, N2, N3, and N4, respectively. Considering the 3D television (100A), in step S220, the 3D television (100A) acquires the number of glasses N1 to be communicated and transmits it to the other devices 100B to 100D.

  Next, each stereoscopic video display device 100 receives the number of glasses counted from the other stereoscopic video display devices 100 (S221). For example, considering the 3D television (100A), in step S221, the 3D television (100A) receives the number of glasses N2 to N4 communicated from the other devices 100B to 100D.

  Each stereoscopic video display device 100 compares the number of glasses counted by itself with the number of glasses received from another stereoscopic video display device 100 to determine whether the number of glasses counted by itself is the maximum. Determination is made (S222). For example, the 3D television (100A) determines whether or not the glasses number N1 is larger than the glasses numbers N2 to N4 of the other devices 100B to 100D. Then, when the number of glasses counted by itself is maximum, it is determined to function as the main device, and “1” is set to the main flag (S223). On the other hand, when there is a stereoscopic image display device 100 having a number of glasses larger than the number of glasses counted by itself, the device itself does not function as a main device, and sets “0” in the main flag (S224).

  In this way, the stereoscopic video display device 100 having the largest number of glasses around can be caused to function as the main device. Note that the processing in FIG. 16 may be continuously repeated, or may be executed when the synchronization signal from the stereoscopic video display device 100 functioning as the main device is not received.

(Determination of the main device based on the distance from the device that was functioning as the main device)
Next, a case where the main device is determined based on the distance from the device functioning as the main device will be described with reference to FIGS. FIG. 17 is an explanatory diagram for explaining a process of determining the 3D image display device 100 closest to the 3D image display device 100 functioning as the main device as the main device. FIG. 18 is an explanatory diagram for describing processing for determining the glasses 200 closest to the glasses 200 functioning as the main device as the main device. FIG. 19 is a flowchart illustrating processing for determining the main device based on the distance from the device functioning as the main device.

  By making the device closest to the device functioning as the main device in the stereoscopic image system 1 a new main device, the configuration of the stereoscopic image system 1 is not greatly changed, and the stereoscopic image system 1 is continuously stabilized. It is thought that it can be operated. When the main device is the stereoscopic video display device 100, the user is likely to pay attention to the stereoscopic video display device 100 that is closest thereto.

  For example, as shown in FIG. 17, there are a 3D television (100A), a 3D display PC1 (100B), a 3D display PC2 (100C), and a 3D projector (100D) as the stereoscopic video display device 100 constituting the stereoscopic image system 1. And Here, it is assumed that the power of the 3D television (100A) functioning as the main device is turned off. At this time, the 3D display PC1 (100B) closest to the 3D television (100A) becomes a new main device, and a synchronization signal is transmitted to each device constituting the stereoscopic image system 1.

  Further, for example, as illustrated in FIG. 18, it is assumed that three glasses (200A to 200C) exist in the stereoscopic image system 1, and the glasses 1 (200A) function as a main device. At this time, when the power of the glasses 1 (200A) is turned off, the glasses 2 (200B) closest to the glasses 1 (200A) becomes a new main device, and a synchronization signal is transmitted to each device constituting the stereoscopic image system 1. To come. Of course, as shown in FIGS. 17 and 18, it is not necessary to switch the main device only between the stereoscopic image display devices 100 or only between the glasses 200, and the main device is switched in consideration of all the devices that can be the main device. Also good.

  Specifically, as shown in FIG. 19, first, a device that can be a main device among the devices constituting the stereoscopic image system 1 measures the distance between the current main device and itself and transmits it to other devices. (S230). The distance between the current main device and itself can be measured based on, for example, the reception strength of a synchronization signal transmitted from the main device, the reception time of a response to a signal transmitted to the main device, or the like. In this case, the device that can be the main device measures the distance from the main device before the main device is turned off. When the distance from the main device can be measured after the main device is turned off, the distance does not necessarily have to be measured before the main device is turned off. The measured distance is Ln (n is a number for identifying the device).

  For example, in FIG. 17, the 3D display PC1 (100B) and the 3D display PC2 (100C) that can function as the main device measure the distance from the 3D television (100A) that is the main device. Let this distance be L1 and L2, respectively. And 3D display PC1 (100B) and 3D display PC2 (100C) transmit the measured distance to another apparatus, respectively.

  Next, the device that can be the main device receives the measured distance from the other device to the main device (S231). For example, in the example of FIG. 17, the 3D display PC1 (100B) receives the distance L2 from the 3D display PC2 (100C), and the 3D display PC2 (100C) receives the distance L1 from the 3D display PC1 (100B).

  Then, each device compares the distance to its main device with the distance to the main device received from other devices, and is the distance to its own main device minimum and is it not possible to receive a synchronization signal? It is determined whether or not (S232). For example, the 3D display PC1 (100B) determines whether the distance L1 to the main device is smaller than the distance L2 to the main device of the 3D display PC2 (100C) and whether a synchronization signal is received. Then, when the distance L1 is the minimum and no synchronization signal is received, it is determined that the 3D display PC1 (100B) functions as the main device, and “1” is set to the main flag (S233). On the other hand, when there is a device closer to the main device than the distance L1, or when a synchronization signal can be received from another device, the device itself does not function as the main device and sets “0” in the main flag (S234).

  In this way, the device closest to the device that has been functioning as the main device in the stereoscopic image system 1 can be made to function as a new main device. Note that the processing in FIG. 19 may be repeated continuously, or may be executed when the synchronization signal from the stereoscopic video display device 100 functioning as the main device is not received.

(Determination of main device based on priority)
Next, based on FIGS. 20-22, the case where a main apparatus is determined based on a priority is demonstrated. 20 and 21 are explanatory diagrams for explaining the process of determining the main device based on the priority. FIG. 22 is a flowchart illustrating processing for determining a main device based on priority.

  In this example, a priority for functioning as a main device is set in advance for a device that can be a main device among the devices constituting the stereoscopic image system 1, and the main device is determined based on the priority. The priority is determined by the user, and can be determined so that, for example, the priority of a device with high use frequency is high.

  For example, in the stereoscopic image system 1 shown in FIG. 20, it is assumed that there are 3D television (100A), 3D display PC1 (100B), 3D display PC2 (100C), and 3D projector (100D) as devices that can be main devices. At this time, the priority for functioning as the main device is set in the order of 3D display PC2 (100C), 3D display PC1 (100B), 3D television (100A), and 3D projector (100D). In FIG. 20, the 3D display PC 2 (100C) having the highest priority functions as the main device. When the power of the 3D display PC2 (100C) as the main device is turned off, the 3D display PC1 (100B) having the highest priority among the activated devices becomes a new main device as shown in FIG. A synchronization signal is transmitted to each device constituting the image system 1.

  Specifically, as illustrated in FIG. 22, first, a device that can be a main device among the devices configuring the stereoscopic image system 1 transmits priority information about a preset self and priority to another device. Then, priority information of other devices is received (S240). The priority is Yn (n is a number for identifying a device), and the higher the priority, the larger the value.

  For example, in FIG. 20, the priorities of the 3D television (100A), 3D display PC1 (100B), 3D display PC2 (100C), and 3D projector (100D) are Y1, Y2, Y3, and Y4. In FIG. 21, when the power of the 3D display PC 2 (100C) functioning as the main device is turned off, the 3D television (100A), 3D display PC 1 (100B), and 3D projector (100D) that can function as other main devices ) Transmits its own priority Y1, Y2, Y4 to the other device and receives the priority of the other device.

  Next, each device compares its own priority with the priority received from another device, and determines whether or not its own priority is the maximum (S241). For example, the 3D television (100A) determines whether or not its own priority Y1 is higher than the priorities Y2 and Y4 of the 3D display PC1 (100B) and the 3D projector (100D). When its own priority Y1 is the maximum, it is determined that the 3D television (100A) functions as the main device, and “1” is set to the main flag (S242). On the other hand, when there is a device with higher priority than the 3D television (100A), the device itself does not function as the main device, and sets “0” in the main flag (S243).

  In this way, the main device can be determined and functioned based on the priority set in advance in the stereoscopic image system 1. Note that the processing in FIG. 22 may be repeated continuously, or may be executed when the synchronization signal from the stereoscopic video display device 100 functioning as the main device is not received.

  Note that one main device may be determined by combining a plurality of the determination processes of the three main devices described above. For example, the above three main device determination processes may be considered equally, or the three may be considered with different weights.

  The configuration and operation of the stereoscopic image system 1 according to the present embodiment have been described above. The stereoscopic image system 1 determines the display timing or opening / closing timing of a plurality of stereoscopic video display devices 100 and at least one glasses 200 constituting the system 1 by the same synchronization signal. Accordingly, even if any of the glasses 200 is used to view the video displayed on the stereoscopic video display device 100, stereoscopic viewing is possible. In addition, even if it does not have a function as a transmitter that generates and transmits a synchronization signal, it can operate in synchronization with other devices as long as it can receive the synchronization signal from any of the devices constituting the stereoscopic image system 1. it can.

  Further, the content displayed on each stereoscopic video display device 100 may be different. For example, if there is a PC with a 3D TV and a 3D display in the same room, and there are people watching each of them, each person can watch a synchronized 3D image regardless of the screen on the TV or PC. Can do.

  The preferred embodiments of the present disclosure have been described in detail above with reference to the accompanying drawings, but the technical scope of the present disclosure is not limited to such examples. It is obvious that a person having ordinary knowledge in the technical field of the present disclosure can come up with various changes or modifications within the scope of the technical idea described in the claims. Of course, it is understood that it belongs to the technical scope of the present disclosure.

The following configurations also belong to the technical scope of the present disclosure.
(1)
The display timing of the right-eye video and the left-eye video of the video data to be displayed on the display unit is determined, and at least one pair of glasses worn by the user when viewing another stereoscopic video display device and the stereoscopic video from the display timing. A synchronization unit for generating a synchronization signal to be synchronized;
A display control unit that displays the right-eye video and the left-eye video of the video data on the display unit based on the display timing;
A transmission unit that transmits the synchronization signal generated by the synchronization unit to the other stereoscopic image display device and the glasses;
A stereoscopic image display device comprising:
(2)
A receiver that receives the synchronization signal transmitted from the other stereoscopic image display device or the glasses that is the main device that generates the synchronization signal;
The stereoscopic image display device according to (1), wherein the synchronization unit controls generation and transmission of the synchronization signal based on whether the reception unit has received the synchronization signal from the main device.
(3)
When the synchronization signal is received by the reception unit, the synchronization unit determines the display timing of the right-eye video and the left-eye video of the video data based on the received synchronization signal, and determines the display timing. The three-dimensional image display device according to (2), which is output to the display controller.
(4)
The synchronization unit generates the synchronization signal when the reception unit does not receive the synchronization signal, determines the display timing based on the generated synchronization signal, and outputs the display timing to the display control unit. The stereoscopic image display device according to (2) or (3), wherein the synchronization signal is output to a transmission unit.
(5)
A receiver that receives the synchronization signal transmitted from the other stereoscopic image display device or the glasses that is the main device that generates the synchronization signal;
When no sync signal is received from the main device,
The transmitting unit transmits the number of the glasses in communication with the stereoscopic video display device to the other stereoscopic video display device capable of communicating,
The receiving unit receives the number of the glasses in communication with the other stereoscopic video display device from the other stereoscopic video display device;
The synchronization signal control unit generates the synchronization signal when the number of the glasses is larger than the number of the glasses in communication with the other 3D image display device, and any one of (1) to (4) The stereoscopic image display device according to item.
(6)
A receiver that receives the synchronization signal transmitted from the other stereoscopic image display device or the glasses that is the main device that generates the synchronization signal;
When no sync signal is received from the main device,
The transmission unit transmits the distance to the main device to the stereoscopic video display device and the glasses other than the main device,
The receiving unit receives a distance from the main device from the stereoscopic image display device and the glasses other than the main device,
The synchronization signal control unit generates the synchronization signal when a distance from the main device is smaller than a distance from the other stereoscopic image display device and the main device of the glasses, (1) to (5) The stereoscopic image display device according to any one of the above.
(7)
The distance from the main device is the stereoscopic video display device according to (6), wherein the distance is determined based on a reception intensity of the synchronization signal received from the main device.
(8)
A receiver that receives the synchronization signal transmitted from the other stereoscopic image display device or the glasses that is the main device that generates the synchronization signal;
When no sync signal is received from the main device,
The three-dimensional object according to any one of (1) to (7), wherein the synchronization signal control unit determines whether or not to generate and transmit the synchronization signal based on a preset priority order. Video display device.
(9)
A receiving unit capable of receiving a synchronization signal transmitted from the other stereoscopic video display device or the glasses other than the other stereoscopic video display device or the glasses as a main device for generating the synchronization signal;
The stereoscopic video display according to (1), wherein the synchronization unit controls generation and transmission of the synchronization signal based on whether the synchronization unit has received the synchronization signal from a device that is not the main device. apparatus.
(10)
The stereoscopic video display device according to any one of (2) to (9), wherein the stereoscopic video display device is capable of bidirectional transmission / reception with at least one of the other stereoscopic video display device and the glasses.
(11)
Synchronized from a main device that generates a synchronization signal that synchronizes a stereoscopic video display device capable of displaying a stereoscopic video and shutter-type glasses worn by the user when viewing the stereoscopic video displayed by each of the stereoscopic video display devices. A receiver for receiving the signal;
Based on the synchronization signal, a shutter control unit that controls the opening and closing timing of the right-eye shutter and the left-eye shutter;
Glasses.
(12)
A synchronization unit for generating the synchronization signal;
A transmission unit for transmitting the synchronization signal to the other stereoscopic image display device and the glasses;
The glasses according to (11), further comprising:
(13)
The glasses according to (12), wherein the synchronization unit controls generation and transmission of the synchronization signal based on whether the reception unit has received the synchronization signal from the main device.
(14)
When the synchronization signal is received by the reception unit, the synchronization unit determines opening / closing timings of the right-eye shutter and the left-eye shutter based on the received synchronization signal, and determines the opening / closing timing The glasses according to (13), which are output to a shutter control unit.
(15)
The synchronization unit causes the synchronization signal generation unit to generate the synchronization signal when the reception unit does not receive the synchronization signal, determines the opening / closing timing based on the generated synchronization signal, and the shutter The glasses according to (13) or (14), wherein the glasses are output to the control unit and the synchronization signal is output to the transmission unit.
(16)
The spectacles according to any one of claims (11) to (15), wherein the reception unit can also receive a synchronization signal transmitted from the stereoscopic image display device other than the main device or the spectacles. .

DESCRIPTION OF SYMBOLS 1 Stereoscopic image system 100 Stereoscopic image display apparatus 110 Reception part 120 Synchronization signal control / generation part 130 Display control part 140 Display part 150 Transmission part 200 Glasses 210 Reception part 220 Shutter control part 230 Shutter for right eye 240 Shutter for left eye 240 Synchronization 250 Signal control / generation unit 260 Transmitter

Claims (18)

The display timing of the right-eye video and the left-eye video of the video data to be displayed on the display unit is determined, and at least one pair of glasses worn by the user when viewing another stereoscopic video display device and the stereoscopic video from the display timing. A synchronization unit for generating a synchronization signal to be synchronized;
A display control unit that displays the right-eye video and the left-eye video of the video data on the display unit based on the display timing;
A transmission unit that transmits the synchronization signal generated by the synchronization unit to the other stereoscopic image display device and the glasses;
A stereoscopic image display device comprising: A receiver that receives the synchronization signal transmitted from the other stereoscopic image display device or the glasses that is the main device that generates the synchronization signal;
The stereoscopic image display apparatus according to claim 1, wherein the synchronization unit controls generation and transmission of the synchronization signal based on whether the reception unit has received the synchronization signal from the main device.   When the synchronization signal is received by the reception unit, the synchronization unit determines the display timing of the right-eye video and the left-eye video of the video data based on the received synchronization signal, and determines the display timing. The three-dimensional image display apparatus according to claim 2, wherein the stereoscopic image display apparatus outputs the display control unit.   The synchronization unit generates the synchronization signal when the reception unit does not receive the synchronization signal, determines the display timing based on the generated synchronization signal, and outputs the display timing to the display control unit. The stereoscopic video display device according to claim 2, wherein the synchronization signal is output to a transmission unit. A receiver that receives the synchronization signal transmitted from the other stereoscopic image display device or the glasses that is the main device that generates the synchronization signal;
When no sync signal is received from the main device,
The transmitting unit transmits the number of the glasses in communication with the stereoscopic video display device to the other stereoscopic video display device capable of communicating,
The receiving unit receives the number of the glasses in communication with the other stereoscopic video display device from the other stereoscopic video display device;
2. The stereoscopic video display device according to claim 1, wherein the synchronization signal control unit generates the synchronization signal when the number of the glasses is larger than the number of the glasses in communication with the other stereoscopic video display device. A receiver that receives the synchronization signal transmitted from the other stereoscopic image display device or the glasses that is the main device that generates the synchronization signal;
When no sync signal is received from the main device,
The transmission unit transmits the distance to the main device to the stereoscopic video display device and the glasses other than the main device,
The receiving unit receives a distance from the main device from the stereoscopic image display device and the glasses other than the main device,
2. The stereoscopic video according to claim 1, wherein the synchronization signal control unit generates the synchronization signal when a distance from the main device is smaller than a distance from the other stereoscopic video display device and the main device of the glasses. Display device.   The stereoscopic image display device according to claim 6, wherein the distance from the main device is determined based on a reception intensity of the synchronization signal received from the main device. A receiver that receives the synchronization signal transmitted from the other stereoscopic image display device or the glasses that is the main device that generates the synchronization signal;
When no sync signal is received from the main device,
The stereoscopic video display apparatus according to claim 1, wherein the synchronization signal control unit determines whether to generate and transmit the synchronization signal based on a preset priority order. A receiving unit capable of receiving a synchronization signal transmitted from the other stereoscopic video display device or the glasses other than the other stereoscopic video display device or the glasses as a main device for generating the synchronization signal;
The stereoscopic image display device according to claim 1, wherein the synchronization unit controls generation and transmission of the synchronization signal based on whether the reception unit has received the synchronization signal from a device that is not the main device. .   The stereoscopic image display device according to claim 2, wherein the stereoscopic image display device can bidirectionally transmit / receive to / from at least one of the other stereoscopic image display device and the glasses. Synchronized from a main device that generates a synchronization signal that synchronizes a stereoscopic video display device capable of displaying a stereoscopic video and shutter-type glasses worn by the user when viewing the stereoscopic video displayed by each of the stereoscopic video display devices. A receiver for receiving the signal;
Based on the synchronization signal, a shutter control unit that controls the opening and closing timing of the right-eye shutter and the left-eye shutter;
Glasses. A synchronization unit for generating the synchronization signal;
A transmission unit for transmitting the synchronization signal to the other stereoscopic image display device and the glasses;
The eyeglasses according to claim 11, further comprising:   The glasses according to claim 12, wherein the synchronization unit controls generation and transmission of the synchronization signal based on whether the reception unit has received the synchronization signal from the main device.   When the synchronization signal is received by the reception unit, the synchronization unit determines opening / closing timings of the right-eye shutter and the left-eye shutter based on the received synchronization signal, and determines the opening / closing timing The spectacles according to claim 13, which is output to a shutter control unit.   The synchronization unit causes the synchronization signal generation unit to generate the synchronization signal when the reception unit does not receive the synchronization signal, determines the opening / closing timing based on the generated synchronization signal, and the shutter The glasses according to claim 13, wherein the glasses are output to the control unit and the synchronization signal is output to the transmission unit.   The spectacles according to claim 11, wherein the reception unit can also receive a synchronization signal transmitted from the stereoscopic image display device other than the main device or the spectacles. At least one of a plurality of stereoscopic video display devices capable of displaying a stereoscopic video and at least one shutter-type glasses worn by the user when viewing the stereoscopic video displayed by each of the stereoscopic video display devices Generating a synchronization signal for synchronizing the stereoscopic image display device and the glasses;
Transmitting the generated synchronization signal to the other stereoscopic image display device and the glasses;
Performing display control of each stereoscopic video display device and shutter control of the glasses based on the received synchronization signal;
Including a synchronization method. A plurality of stereoscopic video display devices capable of displaying stereoscopic video;
At least one shutter-type glasses worn by a user when viewing a stereoscopic image displayed by each of the stereoscopic image display devices;
Consists of
At least one of the stereoscopic video display device and the glasses is:
A synchronization unit that generates a synchronization signal for synchronizing the stereoscopic image display device and the glasses;
A transmission unit for transmitting the synchronization signal to the other stereoscopic image display device and the glasses;
A stereoscopic image system comprising:

Images