JP2011118133A - Stereoscopic image display system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve such a problem that states of liquid crystal shutter eyeglasses and of a stereoscopic image display device cannot be automatically controlled depending on whether or not a person wears the liquid crystal shutter eyeglasses, in the liquid crystal shutter eyeglasses and the stereoscopic image display device. <P>SOLUTION: The stereoscopic image display device includes a signal production part producing a first control signal for controlling the shutter synchronization of a video for a right eye and a video for a left eye when a stereoscopic video is viewed and a first control signal transmission part transmitting the first control signal. The liquid crystal shutter eyeglasses include a second control signal receiving part receiving the first control signal from the stereoscopic image display device, a temperature sensor provided at a nose pad and an ear pad, and a second control signal transmission part transmitting a second control signal so as to control the stereoscopic image display of the stereoscopic image display device by the detection result of the temperature sensor. Thus, the states of the liquid crystal shutter eyeglasses and the stereoscopic image display device are automatically controlled by the liquid crystal shutter eyeglasses. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to time-division liquid crystal shutter glasses type liquid crystal shutter glasses and a stereoscopic image display system using a stereoscopic image display device.

  Conventional time-division liquid crystal shutter glasses type liquid crystal shutter glasses and a stereoscopic image display system using a stereoscopic image display device are known in the configuration shown in FIG. 4 (see Patent Document 1). FIG. 4 is a configuration diagram of conventional liquid crystal shutter glasses and a stereoscopic image display device, and FIG. 5 is a principle diagram of conventional liquid crystal shutter glasses and a stereoscopic image display device. Moreover, the same three-dimensional image display system is applied also to the medical use (refer patent document 2).

  As shown in FIG. 5, the stereoscopic image display apparatus 200 such as a television displays images to be displayed at high speed in the order of a left eye image 501, a right eye image 502, a left eye image 501, a right eye image 502. Switch. At the same time, the stereoscopic image display apparatus 200 transmits a shutter synchronization / control signal 320 to the liquid crystal shutter glasses 100 from the control signal transmission unit 210 using infrared rays or the like. The shutter synchronization / control signal 320 is one of the remote operation signals of the stereoscopic image display apparatus 200, and is a code for identifying shutter switching and the image at that time is a left-eye image or a right-eye image. It is a code signal composed of a code for distinguishing whether or not there is.

  The stereoscopic video display device 200 is also equipped with a control signal receiving unit 220, and receives a control signal (code signal) 311 such as an infrared ray transmitted from a remote control signal transmission unit device 440 such as a remote controller. When the stereoscopic image display apparatus 200 can display both 3D images and 2D images, the 3D image / 2D image must be switched and the shutter synchronization / control signal 320 must be sent / stopped. This is realized by transmitting a signal for controlling switching of 3D image / 2D image of the stereoscopic image display device 200 and transmission / stop of shutter synchronization / control signal from the control signal transmission device 440.

  The liquid crystal shutter glasses 400 that receive the shutter synchronization / control signal 320 are configured as glasses similar to normal glasses, and are equipped with liquid crystal shutters 110L and 110R corresponding to the left and right eyes, and the control signal receiving unit 120. In the liquid crystal shutter glasses 400, the control signal receiving unit 120 receives the shutter synchronization / control signal 320, and switches the left and right liquid crystal shutters 110L and 110R on / off accordingly.

  With the above configuration, in the conventional liquid crystal shutter glasses 400 of the time-division liquid crystal shutter glasses method and the stereoscopic image display device 200, when a person wears the liquid crystal shutter glasses 400 and sees the image of the stereoscopic image display device 200, the stereoscopic image display device 200 An image 503 can be seen.

  As is clear from FIG. 4, the control signal receiving unit 120 of the liquid crystal shutter glasses 400 must be small, and therefore, a small battery such as a button battery is used as a power source. Further, when the image of the stereoscopic image display device 200 is viewed without the liquid crystal shutter glasses 400 being worn, the image appears blurred. Therefore, in the case of the stereoscopic image display apparatus 200 capable of displaying both 3D images and 2D images, when the liquid crystal shutter glasses 400 are worn, “the image of the stereoscopic image display apparatus 200 is converted into a 3D image and shutter synchronization / control is performed. When the glasses are removed, it is necessary to switch to “2D image of stereoscopic image display device 200 and stop shutter synchronization / control signal”.

JP 08-265863 A JP 2001-051113 A

  However, in the conventional configuration, even when a person is not wearing the liquid crystal shutter glasses, if the shutter synchronization / control signal is transmitted from the stereoscopic image display device 200, the liquid crystal shutter glasses 400 receive it and the right and left The liquid crystal shutter is driven to waste the small battery in the liquid crystal shutter glasses, and there is a problem that the usage time of the liquid crystal shutter glasses 400 is shortened. In the conventional configuration, when the stereoscopic image display device 200 can display both 3D images and 2D images, the remote control signal transmission device 440 such as a remote controller is not required. Switching between 2D images cannot be performed, and switching between 3D images and 2D images must be performed independently of the person wearing / removing the liquid crystal shutter glasses 400. It was.

  The present invention solves the above-described conventional problems. It is determined whether a person is wearing or not wearing liquid crystal shutter glasses, switching between 3D image / 2D image of a stereoscopic image display device, and driving of a liquid crystal shutter. An object of the present invention is to provide liquid crystal shutter glasses for controlling the camera.

  In order to solve the conventional problems, a stereoscopic image display system of the present invention is a stereoscopic image display system including liquid crystal shutter glasses and a stereoscopic image display device, and the stereoscopic image display device receives a control signal from the liquid crystal shutter glasses. A first control signal receiving unit that receives the first control signal, a signal generation unit that generates a first control signal that controls shutter synchronization of the right-eye video and the left-eye video when viewing a stereoscopic video, and a first control A liquid crystal shutter glasses based on the first control signal and a second control signal receiving unit that receives the first control signal from the stereoscopic image display device. Controls the stereoscopic image display of the stereoscopic image display device based on the liquid crystal shutter that switches between the shutters of the right eye and the left eye, the temperature sensor provided in the nose pad and the ear pad, and the detection result of the temperature sensor. Comprising a second control signal transmitting unit that transmits the second control signal, to the.

  With this configuration, the stereoscopic image display device sends out shutter synchronization / control signals when a person puts on and wears liquid crystal shutter glasses (the stereoscopic image display device can display both 3D images and 2D images. In this case, in addition to the above, 3D image display is turned on), and the liquid crystal shutter of the liquid crystal shutter glasses is driven. Conversely, the stereoscopic image display device stops sending shutter synchronization / control signals when a person removes and removes the liquid crystal shutter glasses (the stereoscopic image display device can display both 3D images and 2D images. In this case, in addition to the above, 2D image display is on), and the liquid crystal shutter of the liquid crystal shutter glasses stops.

  As described above, according to the liquid crystal shutter glasses of the present invention, the shutter synchronization / control signal is transmitted from the stereoscopic image display device only when a person wears the liquid crystal shutter glasses and only when the person wears the liquid crystal shutter glasses. Since the liquid crystal shutter is driven, the power consumption of the small battery in the liquid crystal shutter glasses can be reduced.

  When the stereoscopic image display device can display both 3D images and 2D images, the stereoscopic image display device can be displayed only by putting on / off the liquid crystal shutter glasses of the present invention without using a remote control signal transmission unit such as a remote controller. Switching between the 3D image and 2D image of the display device is possible, and the operability is improved.

Configuration diagram of liquid crystal shutter glasses and stereoscopic image display device in Embodiment 1 of the present invention 1 is a block diagram of liquid crystal shutter glasses and a stereoscopic image display device according to a first embodiment of the present invention. The figure which shows the output waveform of the AND circuit in the liquid crystal shutter glasses in Example 1 of this invention, and the state and operation | movement of liquid crystal shutter glasses with respect to it Configuration diagram of conventional liquid crystal shutter glasses and stereoscopic image display device Principle diagram of conventional liquid crystal shutter glasses and stereoscopic image display device

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

  FIG. 1 is a configuration diagram of liquid crystal shutter glasses and a stereoscopic image display device according to Embodiment 1 of the present invention. In FIG. 1, the same components as those in FIG. FIG. 2 is a block diagram of the liquid crystal shutter glasses and the stereoscopic image display device according to the first embodiment of the present invention. FIG. 3 shows the output waveform of the AND circuit in the liquid crystal shutter glasses according to the first embodiment of the present invention, and the state and operation of the liquid crystal shutter glasses corresponding thereto.

  First, the configuration of the present invention will be described.

  As shown in FIG. 1, the liquid crystal shutter glasses 100 of the present invention are equipped with temperature sensors 130L, 130R, 130l, and 130r at four locations, the left and right pads (nose pads) and the left and right modern (ear pads). Thus, the body temperature is detected by these, and it is determined whether a person is wearing the liquid crystal shutter glasses 100. In addition, the liquid crystal shutter glasses 100 of the present invention are equipped with a control signal transmission unit 140 for controlling the stereoscopic image display apparatus 200 so as to transmit a desired shutter synchronization / control signal 320 from the control signal transmission unit 140. When the control signal 310 or the stereoscopic image display apparatus 200 can display both 3D images and 2D images, the control signal 310 for controlling switching of 3D images / 2D images is transmitted by infrared rays or the like.

  Next, the operation of the liquid crystal shutter glasses 100 of the present invention will be described.

  As shown in FIG. 2, in the liquid crystal shutter glasses 100 of the present invention, power is supplied to a control signal receiving unit 120, a decoder 121, and a shutter drive circuit 111 from a power supply VDD 151 such as a small battery. It is turned on / off by the switch 152 controlled by the output of 153, and the power consumption is reduced as compared with the case where the power supply is always on. The signal generation IC 141 detects the rise / fall of the output of the AND circuit 153, sends / stops the shutter synchronization / control signal 320 to the stereoscopic image display device 200, and a control signal for switching between the 3D image / 2D image. (When the stereoscopic image display device 200 can display both 3D images and 2D images), the signal transmission unit 140 shapes and transmits the control signal, and the stereoscopic image display device 200 is controlled. Yes.

  The AND circuit 153 is configured so that when “a person is wearing glasses”, the temperature sensors 130L, 130R, 130l mounted on the left and right pads (nose pads) and the left and right modern pins (ear pads), Since 130r is all “High”, “High waveform 330” is output, and when “Human is taking off glasses”, one or more of the four temperature sensors 130L, 130R, 130l, and 130r are “Low”. Therefore, “Low waveform 331” is output.

  The AND circuit 153 outputs a “rising waveform 332” when “a person wears glasses” and outputs a “falling waveform 333” when “a person removes glasses”.

  When the AND circuit 153 outputs “High waveform 330 (a person wears glasses)”, the switch 152 is turned on, and the control signal receiving unit 120, the decoder 121, and the shutter driving circuit 111 are supplied from the power supply VDD 151. Power is supplied. When the shutter synchronization / control signal 320 such as infrared rays is transmitted from the stereoscopic image display apparatus 200 with the switch 152 turned on, the shutter synchronization / control signal 320 is received and shaped by the control signal receiving unit 120 and is used as a code signal. This is supplied to the decoder 121. The decoder 121 decodes the received signal and sends it to the shutter drive circuit 111. The shutter drive circuit 111 performs the left eye and right eye shutter operations of the liquid crystal shutter 110 in accordance with the control signal supplied from the decoder 121.

  On the contrary, when the AND circuit 153 outputs “Low waveform 331 (the person removes the glasses)”, the switch 152 is turned off, and the control signal receiving unit 120, the decoder 121, and the shutter driving circuit 111 are supplied with the power supply VDD 151. Even if the shutter synchronization / control signal 320 is sent from the stereoscopic image display apparatus 200, the liquid crystal shutter 110 does not operate.

  When the AND circuit 153 “outputs the rising waveform 332 (a person wears glasses)”, the signal generation IC 141 detects the rising, and the stereoscopic image display device 200 displays the 3D image. A code signal for controlling the display to be turned on and starting the transmission of the shutter synchronization / control signal 320 is generated and sent to the control signal transmission unit 140. Then, the control signal transmission unit 140 shapes the waveform of the code signal 310 supplied from the signal generation IC 141 and sends it to the stereoscopic image display apparatus 200.

  The stereoscopic image display apparatus 200 turns on 3D image display and transmits a shutter synchronization / control signal 320 in accordance with a control signal 310 such as infrared rays supplied from the signal transmission unit 140.

  Conversely, when the AND circuit 153 “outputs the falling waveform 333 (a person removes the glasses)”, the signal generation IC 141 detects the falling, and the stereoscopic image display device 200 includes the stereoscopic image display device 200. The 2D image display is turned on, and a code signal for controlling to stop the transmission of the shutter synchronization / control signal 320 is generated and sent to the control signal transmission unit 140. Then, the control signal transmission unit 140 shapes the waveform of the code signal 310 supplied from the signal generation IC 141 and sends it to the stereoscopic image display apparatus 200. The stereoscopic image display apparatus 200 turns on the 2D image display according to the control signal 310 such as infrared rays supplied from the signal transmission unit 121 and stops sending the shutter synchronization / control signal 320.

  According to such a configuration, the temperature sensors 130L, 130R, 130l, and 130r are built in the left and right pads (nose pads) and the left and right modern pads (ear pads) of the liquid crystal shutter glasses 100. By making the output the input of the AND circuit 153, it is possible to detect the four states of the glasses (hung, removed, hung, removed). Furthermore, the control signal transmission unit 120 and the switch 152 are mounted on the liquid crystal shutter glasses 100, and these two are controlled by the output of the AND circuit 153, so that the liquid crystal shutter glasses 100 and the stereoscopic image display device 200 are in the state of glasses. Can be automatically controlled, the power consumption of the liquid crystal shutter glasses 100 can be reduced, and the operability of the stereoscopic image display apparatus 200 can be improved.

  Since the liquid crystal shutter glasses and the stereoscopic image display device of the present invention can reduce the power consumption of the liquid crystal shutter glasses, the size of the liquid crystal shutter glasses and the improvement in functionality of the small battery in the glasses can be further improved. This is useful for downsizing and increasing power consumption.

  In addition, the liquid crystal shutter glasses and the stereoscopic image display device of the present invention can be used only when the stereoscopic image display device can display both 3D images and 2D images by simply putting on / off the liquid crystal shutter glasses. Since switching between 3D images and 2D images is possible, it is useful when used by elderly people or small children who are not good at complicated operations such as remote control.

100 LCD shutter glasses 110 LCD shutter 110L LCD shutter (left eye)
110R LCD shutter (right eye)
111 Shutter Drive Circuit 120 Control Signal Receiver 121 Decoder 130L Temperature Sensor (Left Pad)
130R Temperature sensor (right pad)
130l temperature sensor (left modern)
130r temperature sensor (right modern)
140 Control Signal Transmitter 141 Signal Generation IC (FPGA, etc.)
151 VDD power source 152 switch 153 AND circuit 200 stereoscopic image display device 210 control signal transmission unit 220 control signal reception unit 310 control signal (code signal) transmitted from the liquid crystal shutter glasses
311 Control signal (code signal) transmitted from remote control signal transmitter
320 Shutter synchronization / control signal 330 High waveform of AND circuit (when wearing glasses)
331 AND circuit low waveform (when glasses are removed)
332 AND circuit rising waveform (when wearing glasses)
333 Falling waveform of AND circuit (when glasses are removed)
400 Conventional liquid crystal shutter glasses 440 Remote control signal transmission device 501 Image for left eye 502 Image for right eye 503 Stereoscopic image

Claims (1)

A stereoscopic image display system including liquid crystal shutter glasses and a stereoscopic image display device,
The stereoscopic image display device includes:
A first control signal receiver for receiving a control signal from the liquid crystal shutter glasses;
A signal generation unit that generates a first control signal that controls shutter synchronization between the right-eye video and the left-eye video when viewing a stereoscopic video;
A first control signal transmitter for transmitting the first control signal,
The liquid crystal shutter glasses are
A second control signal receiving unit for receiving a first control signal from the stereoscopic image display device;
A liquid crystal shutter that switches between a right eye shutter and a left eye shutter based on the first control signal;
A temperature sensor for the nose pad and the ear pad,
A second control signal transmission unit that transmits a second control signal to control stereoscopic image display of the stereoscopic image display device according to a detection result of the temperature sensor;
A stereoscopic image display system comprising:

Images