JP2013070314A - Glasses for stereoscopic vision, image display device, image display system and control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce interference in other apparatuses generated due to a synchronization signal.SOLUTION: Glasses 20 includes: a right-eye shutter 23R brought into an open state or a closed state; a left-eye shutter 23L brought into the open state or the closed state; a synchronization signal reception unit 21 for receiving a shutter synchronization signal; and a controller 22 that, when the synchronization signal reception unit 21 receives a first signal as the shutter synchronization signal, brings the shutter 23R into the open state while bringing the shutter 23L into the closed state and, when the synchronization signal reception unit 21 receives a second signal as the shutter synchronization signal, brings the shutter 23L into the open state while bringing the shutter 23R into the closed state.

Description

  The present invention relates to stereoscopic glasses for viewing a 3D image stereoscopically.

  A system using glasses having a liquid crystal shutter (hereinafter referred to as “stereoscopic glasses”) is known as a system for allowing a user to perceive 3D video. In this system, the image display device alternately displays right-eye images and left-eye images. In the stereoscopic glasses, the opening and closing of the right-eye shutter and the left-eye shutter is controlled in synchronization with image switching in the image display device. Patent Document 1 describes that four types of synchronization signals are used as synchronization signals for controlling stereoscopic glasses.

JP 2010-268449 A

  A user who views 3D video may use a remote control device to operate the image display device. In addition, headphones may be worn for more realistic viewing. A remote control device generally performs wireless communication using an infrared signal or the like. In addition, wireless headphones that perform wireless communication are beginning to be used as headphones. When such other devices that perform wireless communication and an image display device that transmits a synchronization signal are used together, the signal may interfere. If the signal interferes, the remote control device becomes difficult to operate, and noise is introduced into the sound of the headphones, which hinders the operation of other devices. Therefore, an object of the present invention is to reduce interference with other devices caused by a synchronization signal.

  In order to solve the above problems, the present invention provides a first shutter for a right eye that is in an open state or a closed state, a second shutter for a left eye that is in an open state or a closed state, and reception that receives a synchronization signal. And when the receiving unit receives the first signal as the synchronization signal, the second shutter is set to the closed state and the first shutter is set to the open state, and the receiving unit sets the second signal as the synchronization signal. Is received, the stereoscopic glasses having the control unit for setting the first shutter to the closed state and setting the second shutter to the open state are provided. According to the stereoscopic glasses, it is possible to reduce interference with other devices caused by the synchronization signal as compared with the case where the synchronization signal in which only one of the first shutter and the second shutter is controlled is used. it can.

  In another preferable aspect, when the receiving unit receives the third signal as the synchronization signal, the control unit sets the first shutter to the open state, and the receiving unit outputs the fourth signal as the synchronization signal. When receiving, the first shutter is set to the closed state, and when the receiving unit receives the fifth signal as the synchronization signal, the second shutter is set to the open state, and the receiving unit receives the sixth signal as the synchronization signal. Upon reception, the second shutter is brought into the closed state. According to the stereoscopic glasses, an image display device that transmits a synchronization signal for controlling only one of the first shutter and the second shutter, or a synchronization signal for controlling both the first shutter and the second shutter. Any of the image display devices that transmit can be used.

  Moreover, in another preferable aspect, the control unit starts an operation of shifting the second shutter to the closed state in accordance with the first signal, and then moves the first shutter to the open state. Selected from a plurality of operation modes including a first mode in which a delay time until starting the first time is a first time and a second mode in which the delay time is a second time longer than the first time Control is performed in one operation mode. According to the stereoscopic glasses, the open / close states of the first shutter and the second shutter can be controlled with different delay times for a plurality of image display devices having different response times.

  In another preferred aspect, the delay time is determined for each frame rate, and the first signal and the second signal are defined for each frame rate. According to the stereoscopic glasses, the delay time can be automatically switched according to the frame rate of the image display device.

  In addition, the present invention provides a three-dimensional structure including a first shutter for the right eye that is opened or closed, a second shutter for the left eye that is opened or closed, and a receiver that receives a synchronization signal. An image display device used together with viewing glasses, wherein a display unit that displays a right-eye image and a left-eye image in a time-sharing manner, and a timing at which the right-eye image is displayed by the display unit, As the synchronization signal, a first signal for causing the second shutter to be in the closed state and the first shutter to be in the open state is transmitted to the stereoscopic glasses, and the image for the left eye is transmitted by the display unit. Is transmitted to the stereoscopic glasses as the synchronization signal, the second signal for bringing the first shutter to the closed state and the second shutter to the open state as the synchronization signal. Part To provide an image display device having a. According to this image display device, it is possible to reduce interference with other devices caused by the synchronization signal as compared with the case where the synchronization signal in which only one of the first shutter and the second shutter is controlled is used. .

  The present invention further includes an image display device and stereoscopic glasses, and the image display device displays a right-eye image and a left-eye image in a time-sharing manner, and the display unit includes the display unit. A first signal is transmitted as a synchronization signal to the stereoscopic glasses according to the timing at which the right-eye image is displayed, and the synchronization signal is determined according to the timing at which the display unit displays the left-eye image. A transmission unit that transmits the second signal to the stereoscopic glasses, and the stereoscopic glasses are in the open state or the closed state, and the first shutter for the right eye that is in the open state or the closed state. A second shutter for the left eye, a receiving unit that receives the synchronization signal, and when the receiving unit receives the first signal as the synchronization signal, the second shutter is closed and the first shutter is In the open state, the receiving unit is Upon receiving the second signal as a period signal, to provide an image display system and a control unit for the open state the second shutter as well as the first shutter in the closed state. According to this image display system, it is possible to reduce interference with other devices caused by the synchronization signal as compared with the case where the synchronization signal in which only one of the first shutter and the second shutter is controlled is used. .

  According to the present invention, the image display device displays the right-eye image and the left-eye image in a time-sharing manner, and the synchronization signal is generated according to the timing at which the image display device displays the right-eye image. Transmitting the first signal to the stereoscopic glasses and transmitting the second signal as the synchronization signal to the stereoscopic glasses in accordance with the timing for displaying the left-eye image; and the stereoscopic glasses Receiving the synchronization signal, and when the stereoscopic glasses receive the first signal as the synchronization signal, the second shutter is closed and the first shutter is opened, and the stereoscopic viewing is performed. When the glasses receive the second signal as the synchronization signal, there is provided a control method including a step of closing the first shutter and opening the second shutter. According to this control method, it is possible to reduce interference with other devices caused by the synchronization signal as compared with the case where the synchronization signal in which only one of the first shutter and the second shutter is controlled is used.

1 is a diagram illustrating an overall configuration of an image display system 1. FIG. FIG. 2 is a block diagram showing a functional configuration of the projector. FIG. 2 is a block diagram showing a hardware configuration of the projector. The block diagram which shows the functional structure of the spectacles 20. FIG. The block diagram which shows the hardware constitutions of the spectacles 20. FIG. FIG. The figure which shows an example of the waveform of a shutter synchronizing signal. The figure which illustrates operation | movement of a shutter. 5 is a flowchart showing the operation of the glasses 20. 6 is a timing chart showing an operation example of the liquid crystal shutter 206.

  FIG. 1 is a diagram showing an overall configuration of an image display system 1 according to an embodiment of the present invention. The image display system 1 includes a projector 10, glasses 20 and a screen SC. The projector 10 (an example of an image display device) is a device that projects an image corresponding to an input video signal onto a screen. In this example, the video indicated by the video signal is a time-divided image for the right eye (hereinafter referred to as “image for right eye”) and an image for left eye (hereinafter referred to as “image for left eye”). It is an image that appears alternately. The screen SC is a plane that displays an image projected from the projector 10. The glasses 20 are stereoscopic glasses for causing the right eye image and the left eye image to be independently viewed by the right eye and the left eye, respectively.

  FIG. 2 is a block diagram illustrating a functional configuration of the projector 10. The projector 10 includes a video acquisition unit 11, an image display unit 12, and a synchronization signal transmission unit 13. The video acquisition unit 11 acquires a video signal from an external device such as a DVD (Digital Versatile Disc) player or a personal computer. The image display unit 12 displays the right eye image and the left eye image included in the video signal acquired by the video acquisition unit 11 in a time-sharing manner. The synchronization signal transmission unit 13 transmits a first signal as a shutter synchronization signal to the glasses 20 according to the timing at which the image display unit 12 displays the right eye image, and the image display unit 12 displays the left eye image. The second signal is transmitted to the glasses 20 as a shutter synchronization signal according to the timing.

  FIG. 3 is a block diagram illustrating a hardware configuration of the projector 10. The projector 10 includes an MCU (Micro Control Unit) 101, a RAM (Random Access Memory) 102, a ROM (Read Only Memory) 103, a video signal receiver 104, a frame rate conversion circuit 105, a panel drive circuit 106, a liquid crystal panel 107, and a light source 108. , A projection optical system 109, a synchronization signal generation circuit 110, an LED (Light Emitting Diode) drive circuit 111, and an LED 112. The MCU 101 is a control device that controls each unit of the projector 10 by executing a program. The RAM 102 is a volatile storage device that stores data. The ROM 103 is a nonvolatile storage device that stores various programs and data.

  The video signal receiver 104 acquires a video signal from an external device. The video signal includes a right-eye image, a left-eye image, and a synchronization signal (horizontal synchronization signal and vertical synchronization signal). The MCU 101 stores the video signal acquired by the video signal receiver 104 in the RAM 102 as a right-eye image or a left-eye image for each frame. The frame rate conversion circuit 105 converts the frame rate of the video signal so that the display switching frequency of the right-eye image and the left-eye image in one second matches the frame rate of the projector 10.

  The MCU 101 enlarges or reduces the right-eye image and the left-eye image stored in the RAM 102 in accordance with the resolution of the liquid crystal panel 107. The MCU 101 writes the right-eye image and the left-eye image after enlargement or reduction in the RAM 102. The panel drive circuit 106 generates a panel drive signal for driving the liquid crystal panel 107 based on the right eye image and the left eye image read from the RAM 102. The panel drive circuit 106 outputs a panel drive signal to the liquid crystal panel 107. The liquid crystal panel 107 has a plurality of pixels arranged in a matrix. The liquid crystal panel 107 is used as a light valve that modulates the transmittance of light emitted from the light source 108 for each pixel based on a panel drive signal. The light modulated by the liquid crystal panel 107 is enlarged by the projection optical system 109 and projected onto the screen SC. The synchronization signal generation circuit 110 generates a shutter synchronization signal for synchronizing the image displayed on the liquid crystal panel 107 and the opening / closing of the shutter in the glasses 20 and outputs the shutter synchronization signal to the LED drive circuit 111. The LED drive circuit 111 generates an LED drive signal for driving the LED 112 based on the shutter synchronization signal, and outputs the LED drive signal to the LED 112. The LED 112 outputs light (for example, infrared rays) in a predetermined wavelength band based on the LED drive signal. As described above, the shutter synchronization signal is transmitted to the glasses 20 by wireless communication.

  In the projector 10, the video signal receiver 104 controlled by the MCU 101 is an example of the video acquisition unit 11. The frame rate conversion circuit 105, the panel drive circuit 106, the liquid crystal panel 107, the light source 108, and the projection optical system 109 controlled by the MCU 101 are examples of the image display unit 12. The synchronization signal generation circuit 110, the LED drive circuit 111, and the LED 112 controlled by the MCU 101 are an example of the synchronization signal transmission unit 13.

  FIG. 4 is a block diagram showing a functional configuration of the glasses 20. The glasses 20 include a synchronization signal receiving unit 21, a control unit 22, and a shutter 23. The synchronization signal receiving unit 21 receives the shutter synchronization signal transmitted by the projector 10. Six types of synchronization signals are used as the shutter synchronization signal. The control unit 22 controls the open / close state of the shutter 23 when the synchronization signal receiving unit 21 receives the shutter synchronization signal. The shutter 23 includes a right-eye shutter 23R (an example of a first shutter) and a left-eye shutter 23L (an example of a second shutter). The shutter 23R and the shutter 23L are in an open state or a closed state. When the synchronization signal receiving unit 21 receives the first signal as the shutter synchronization signal, the control unit 22 closes the shutter 23L and opens the shutter 23R. When the synchronization signal receiving unit 21 receives the second signal as the shutter synchronization signal, the control unit 22 closes the shutter 23R and opens the shutter 23L. When the synchronization signal receiving unit 21 receives the third signal as the shutter synchronization signal, the control unit 22 keeps the state of the shutter 23L (not changed) while opening the shutter 23R. When the synchronization signal receiving unit 21 receives the fourth signal as the shutter synchronization signal, the control unit 22 controls the shutter 23R to be closed, while maintaining the state of the shutter 23L (not changed). When the synchronization signal receiving unit 21 receives the fifth signal as the shutter synchronization signal, the control unit 22 controls the shutter 23L to the open state, while maintaining the state of the shutter 23R (does not change). When the synchronization signal receiving unit 21 receives the sixth signal as the shutter synchronization signal, the control unit 22 closes the shutter 23L, while maintaining (not changing) the state of the shutter 23R.

  FIG. 5 is a block diagram illustrating a hardware configuration of the glasses 20. The glasses 20 include a CPU 201, a RAM 202, a ROM 203, an infrared sensor 204, a shutter control circuit 205, and a liquid crystal shutter 206. The CPU 201 is a control device that controls each unit of the glasses 20 by executing a program. The RAM 202 is a volatile storage device that stores data. The ROM 203 is a nonvolatile storage device that stores various programs and data. The ROM 203 stores a protocol for generating a shutter control signal from the shutter synchronization signal. “Protocol” refers to information indicating the operation of the liquid crystal shutter 206. The protocol also includes information indicating a correspondence relationship between a specific shutter synchronization signal and the operation of the liquid crystal shutter 206 corresponding to the shutter synchronization signal. The infrared sensor 204 receives light output from the projector 10 and outputs a signal corresponding to the intensity of the received light. This signal is a shutter synchronization signal. The CPU 201 analyzes the content of the signal included in the shutter synchronization signal. The CPU 201 reads a protocol corresponding to the analysis result of the shutter synchronization signal from the ROM 203 and outputs it to the shutter control circuit 205. The shutter control circuit 205 generates a shutter control signal for controlling the liquid crystal shutter 206 based on the protocol acquired from the CPU 201. The shutter control circuit 205 outputs a shutter control signal to the liquid crystal shutter 206. The liquid crystal shutter 206 includes a liquid crystal shutter 206R for the right eye and a liquid crystal shutter 206L for the left eye. The liquid crystal shutter 206 is switched between an open state and a closed state by a shutter control signal. The “open state” refers to a state where the transmittance is equal to or higher than a predetermined threshold value (for example, 90%). The “closed state” refers to a state where the transmittance is equal to or lower than a predetermined threshold value (for example, 10%). If the liquid crystal shutter 206R of the glasses 20 is opened and the liquid crystal shutter 206L is closed at the timing when the projector 10 projects the right eye image, the right eye image is perceived only by the right eye. If the liquid crystal shutter 206L of the glasses 20 is opened and the liquid crystal shutter 206R is closed at the timing when the projector 10 projects the left eye image, the left eye image is perceived only by the left eye. The right eye image and the left eye image are perceived independently by the right eye and the left eye, so that the image displayed on the screen SC looks three-dimensional.

  In the eyeglass 20, the infrared sensor 204 controlled by the CPU 201 is an example of the synchronization signal receiving unit 21. The CPU 201 and the shutter control circuit 205 controlled by the CPU 201 are an example of the control unit 22. The liquid crystal shutter 206 is an example of the shutter 23.

  FIG. 6 is a diagram showing an overview of the glasses 20. The spectacles 20 have a frame, and a liquid crystal shutter 206 is provided in a portion corresponding to a lens of spectacles for correcting vision. The liquid crystal shutter 206R and the liquid crystal shutter 206L open and close according to the shutter synchronization signal. The infrared sensor 204 is provided on the same surface as the liquid crystal shutter 206 in the frame.

  FIG. 7 is a diagram illustrating an example of the waveform of the shutter synchronization signal output from the LED 112. In FIG. 7, the horizontal axis represents time, and the vertical axis represents light intensity. In this example, the shutter synchronization signal indicates the operation timing of the liquid crystal shutter 206. The shutter synchronization signal is composed of 5-bit information. The first bit and the fifth bit indicate the start point and end point of the shutter synchronization signal, respectively. The 3-bit information (the portion represented by C in FIG. 7) of the second to fourth bits indicates the identification number of the operation of the liquid crystal shutter 206. If 3-bit information is used, eight types of operations can be identified. In this example, six types of identifiers are used (that is, six types of operations are defined). In the example of FIG. 7, the shutter synchronization signal indicates the identifier “100”.

  FIG. 8 is a diagram illustrating the operation of the shutter. In this figure, the shutter synchronization signal is represented by a rectangle. The numbers written in the rectangles represent the identifiers indicated by the shutter synchronization signals in decimal numbers. In FIG. 8, the horizontal axis represents time. “L” represents the open / closed state (transmittance) of the liquid crystal shutter 206L, and “R” represents the open / closed state (transmittance) of the liquid crystal shutter 206R. Regarding the operation of the liquid crystal shutter 206, “O” indicates an open state (transmission state), and “C” indicates a close state (non-transmission state). When the shutter synchronization signal indicates the identification number “1” (an example of the first signal), the shutter control circuit 205 outputs to the liquid crystal shutter 206 a shutter control signal for causing the liquid crystal shutter 206 to perform the first operation. . The first operation is an operation in which the liquid crystal shutter 206R starts transition to the open state after the delay time Td has elapsed since the liquid crystal shutter 206L started transition to the closed state. When the shutter synchronization signal indicates the identification number “2” (an example of the second signal), the shutter control circuit 205 outputs a shutter control signal for causing the liquid crystal shutter 206 to perform the second operation to the liquid crystal shutter 206. . The second operation is an operation in which the liquid crystal shutter 206L starts transition to the open state after the delay time Td has elapsed since the liquid crystal shutter 206R started transition to the closed state. Thus, the shutter synchronization signal indicating the identification number “1” or “2” is a signal for controlling the open / closed state of both the liquid crystal shutter 206R and the liquid crystal shutter 206L.

  When the shutter synchronization signal indicates the identification number “3” (an example of the third signal), the shutter control circuit 205 outputs a shutter control signal for causing the liquid crystal shutter 206 to perform the third operation to the liquid crystal shutter 206. . The third operation is an operation in which the liquid crystal shutter 206R starts transition to the open state. When the shutter synchronization signal indicates the identification number “4” (an example of the fourth signal), the shutter control circuit 205 outputs a shutter control signal for causing the liquid crystal shutter 206 to perform the fourth operation to the liquid crystal shutter 206. . The fourth operation is an operation in which the liquid crystal shutter 206R starts transition to the closed state. When the shutter synchronization signal indicates the identification number “5” (an example of the fifth signal), the shutter control circuit 205 outputs to the liquid crystal shutter 206 a shutter control signal for causing the liquid crystal shutter 206 to perform the fifth operation. . The fifth operation is an operation in which the liquid crystal shutter 206L starts transition to the open state. When the shutter synchronization signal indicates the identification number “6” (an example of the sixth signal), the shutter control circuit 205 outputs to the liquid crystal shutter 206 a shutter control signal for causing the liquid crystal shutter 206 to perform the sixth operation. . The sixth operation is an operation in which the liquid crystal shutter 206L starts transition to the closed state. Thus, the shutter synchronization signal indicating the identification numbers “3” to “6” is a signal for controlling the open / close state of only one of the liquid crystal shutter 206R and the liquid crystal shutter 206L.

  FIG. 9 is a flowchart showing the operation of the glasses 20. FIG. 9 shows a process in which the liquid crystal shutter 206 is opened and closed according to one shutter synchronization signal. In step S <b> 1, the infrared sensor 204 receives light output from the projector 10. In step S2, the CPU 201 analyzes the shutter synchronization signal. The CPU 201 reads a protocol corresponding to the identification number indicated by the shutter synchronization signal from the ROM 203 and outputs it to the shutter control circuit 205. The shutter control circuit 205 outputs a shutter control signal corresponding to the protocol to the liquid crystal shutter 206 (steps S3 to S8). The liquid crystal shutter 206 performs first to sixth operations according to the shutter control signal. The eyeglass 20 repeats the above process every time it receives infrared rays from the projector 10.

FIG. 10 is a timing chart showing an operation example of the liquid crystal shutter 206. FIG. 10 shows an example (SH1 in the figure) using the shutter synchronization signal indicating the identification numbers “1” and “2” and the identification number “3” for the common operation of alternately opening and closing the liquid crystal shutters 206R and 206L. To (6) using a shutter synchronization signal indicating “6” (example using no shutter synchronization signal indicating identification numbers “1” and “2”; SH2 in the figure). In FIG. 10, an image of white color (hereinafter referred to as “white image”) is projected on the screen SC as the image for the left eye, and an image of black color (hereinafter referred to as “black image”) as the image for the right eye. An example of projection will be described. “I” in FIG. 10 represents the gradation of an image projected on the screen SC by the projector 10. “W” indicates white and “B” indicates black. In FIG. 10, the shutter synchronization signals SH1 and SH2 are signals for causing the glasses 20 to perform the following operations (1) to (8) (in this example, a white image is used as the left-eye image). The displayed state is the initial state).
(1) At time t1, the liquid crystal shutter 206L starts transition to the closed state.
(2) At time t2 after the lapse of the delay time Td from time t1, the liquid crystal shutter 206R starts transition to the open state.
(3) At time t3, the liquid crystal shutter 206R starts transition to the closed state.
(4) At time t4 after the elapse of the delay time Td from time t3, the liquid crystal shutter 206L starts transition to the open state.
(5) At time t5, the liquid crystal shutter 206L starts transition to the closed state.
(6) At time t6 after the delay time Td has elapsed from time t5, the liquid crystal shutter 206R starts to transition to the open state.
(7) At time t7, the liquid crystal shutter 206R starts transition to the closed state.
(8) At time t8 after the elapse of the delay time Td from time t7, the liquid crystal shutter 206L starts transition to the open state.
In order to reduce crosstalk, the delay time Td is set to be longer than the response time Tr of the liquid crystal panel 107 of the projector 10.

  When the shutter synchronization signal SH1 is used to perform the operation of FIG. 10, the signal is transmitted four times. On the other hand, when the shutter synchronization signal SH2 is used, the signal is transmitted eight times. As described above, when an infrared signal is used in a remote control device, wireless headphones, or the like, if the shutter synchronization signal is transmitted via infrared, the shutter synchronization signal may interfere with other signals. However, if the shutter synchronization signal SH1 is used, the number of times the infrared signal is transmitted is halved compared to the case where the shutter synchronization signal SH2 is used. This reduces the possibility of interference with other devices such as remote control devices or wireless headphones.

<Modification>
The present invention is not limited to the above-described embodiments, and various modifications can be made. Hereinafter, some modifications will be described. Of the modifications described below, two or more may be used in combination.

(1) The delay time may be variable instead of being fixed. For example, the glasses 20 are selected from a first mode in which the delay time is Td1 (an example of the first time) and a second mode in which the delay time is Td2 (an example of the second time) that is longer than the Td1. The operation mode may be used. The operation mode is selected according to the response time Tr in the image display device. The selection of the operation mode may be performed according to a user instruction. In this case, for example, the glasses 20 are provided with a switch. When the user operates this switch, the operation mode is selected. As another example, the operating mode may be automatically selected. In this case, for example, the shutter synchronization signal output from the projector 10 includes information indicating the operation mode. The CPU 201 of the glasses 20 selects an operation mode based on this information. The operation mode is not limited to two.

(2) The delay time Td may be zero. In this case, the liquid crystal shutter 206R and the liquid crystal shutter 206L are simultaneously switched between open and closed states. When the delay time Td is 0, the response time Tr may not be 0, but is preferably 0.

(3) The operation of the glasses 20 may be defined for each frame rate of the projector 10. For example, when there are a projector that operates at a frame rate of 192 Hz and a projector that operates at a frame rate of 240 Hz, the first to sixth operations may be defined for each of the case of the frame rate of 192 Hz and the case of 240 Hz. . In this case, the shutter synchronization signal is composed of 6-bit information. Using the 4th bit information of the 2nd to 5th bits, the 1st to 6th operations are identified for each of the frame rate of 192 Hz and 240 Hz (to define a total of 12 types of operations). Is possible. The identification numbers “1” to “6” may be assigned to the first to sixth operations with a frame rate of 192 Hz, and the identification numbers “7” to “12” may be assigned to the first to sixth operations with a frame rate of 240 Hz. Projectors operating at a frame rate of 192 Hz output signals indicating identification numbers “1” to “6”, and projectors operating at a frame rate of 240 Hz output signals indicating identification numbers “7” to “12”.

(4) The image display device is not limited to the projector 10. The image display device is not limited to a projection type device, and may be a direct-view type image display device such as a liquid crystal display or a plasma display.

(5) The open state or the closed state is not limited to that defined by the transmittance of the liquid crystal shutter 206. For example, the open state and the closed state may be defined by the polarization direction of the liquid crystal shutter 206. For example, a state where the polarization direction is the first direction may be defined as an open state, and a state where the polarization direction is a second direction orthogonal to the first direction may be defined as a closed state. In this case, the liquid crystal shutter 206 has a configuration in which the polarization direction is switched by an electrical signal.

(6) The first shutter and the second shutter are not limited to the liquid crystal shutter 206. For example, mechanical shutters may be used as the first shutter and the second shutter.

(7) The waveform of the shutter synchronization signal is not limited to that shown in FIG. For example, the fifth bit indicating the end point of the shutter synchronization signal may be omitted.

DESCRIPTION OF SYMBOLS 1 ... Image display system, 10 ... Projector, 20 ... Glasses, 11 ... Image | video acquisition part, 12 ... Image display part, 13 ... Synchronization signal transmission part, 21 ... Synchronization signal reception part, 22 ... Control part, 23 ... Shutter, 101 ... MCU, 102 ... RAM, 103 ... ROM, 104 ... Video signal receiver, 105 ... Frame rate conversion circuit, 106 ... Panel drive circuit, 107 ... Liquid crystal panel, 108 ... Light source, 109 ... Projection optical system, 110 ... Synchronization signal generation Circuit 111 111 LED driving circuit 112 LED 201 CPU 202 RAM 203 ROM 204 Infrared sensor 205 Shutter control circuit 206 Liquid crystal shutter

Claims (7)

A first shutter for the right eye that is open or closed;
A second shutter for the left eye that is open or closed;
A receiver for receiving the synchronization signal;
When the receiving unit receives the first signal as the synchronization signal, the second shutter is set to the closed state and the first shutter is set to the open state, and the receiving unit receives the second signal as the synchronization signal. Stereoscopic glasses comprising: a control unit that places the first shutter in the closed state and places the second shutter in the open state. The control unit opens the first shutter when the receiving unit receives the third signal as the synchronization signal, and opens the first shutter when the receiving unit receives the fourth signal as the synchronization signal. When the reception unit receives the fifth signal as the synchronization signal in the closed state, the second shutter is set in the open state when the reception unit receives the fifth signal as the synchronization signal, and when the reception unit receives the sixth signal as the synchronization signal, the second shutter is The stereoscopic glasses according to claim 1, wherein the glasses are in the closed state. The control unit, in response to the first signal, delay time from the start of the operation of transitioning the second shutter to the closed state to the start of the operation of transitioning the first shutter to the open state. Control in one operation mode selected from a plurality of operation modes including a first mode that is a first time and a second mode that is a second time in which the delay time is longer than the first time. The stereoscopic glasses according to claim 1, wherein the glasses are for stereoscopic viewing. The delay time is determined for each frame rate,
The stereoscopic glasses according to claim 3, wherein the first signal and the second signal are defined for each frame rate. Used with stereoscopic glasses having a first shutter for a right eye that is in an open state or a closed state, a second shutter for a left eye that is in an open state or a closed state, and a receiver that receives a synchronization signal An image display device,
A display unit that displays a right-eye image and a left-eye image in a time-sharing manner;
In accordance with the timing at which the right-eye image is displayed by the display unit, a first signal for setting the second shutter to the closed state and the first shutter to the open state is used as the synchronization signal. The first shutter is closed and the second shutter is opened as the synchronization signal according to the timing when the left eye image is displayed on the display unit. An image display apparatus comprising: a transmission unit configured to transmit a second signal for setting a state to the stereoscopic glasses. An image display device;
Stereoscopic glasses and
The image display device includes:
A display unit that displays a right-eye image and a left-eye image in a time-sharing manner;
Depending on the timing at which the display unit displays the right eye image, the first signal is transmitted to the stereoscopic glasses as a synchronization signal, and the display unit displays the left eye image. And a transmission unit that transmits the second signal to the stereoscopic glasses as the synchronization signal,
The stereoscopic glasses are
A first shutter for the right eye that is open or closed;
A second shutter for the left eye that is open or closed;
A receiver for receiving the synchronization signal;
When the receiving unit receives the first signal as the synchronization signal, the second shutter is set to the closed state and the first shutter is set to the open state, and the receiving unit receives the second signal as the synchronization signal. An image display system comprising: a control unit configured to set the first shutter to the closed state and to set the second shutter to the open state. A step in which the image display device displays the right-eye image and the left-eye image in a time-sharing manner;
The image display device transmits a first signal as a synchronization signal to the stereoscopic glasses according to the timing for displaying the right-eye image, and the synchronization signal according to the timing for displaying the left-eye image. Transmitting a second signal to the stereoscopic glasses as:
The stereoscopic glasses receiving the synchronization signal;
When the stereoscopic glasses receive the first signal as the synchronization signal, the second shutter is closed and the first shutter is opened, and the stereoscopic glasses receive the second signal as the synchronization signal. And receiving, the first shutter is closed and the second shutter is opened.

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