JP2014120022A - Display device and method of controlling display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve operability in executing various functions of a display device.SOLUTION: A display device comprises: a projection unit 3 that displays an image on a screen SC; a position detection unit 150 that detects an indicated position of an indicator 70 in the screen SC; and a control section 103 that, when a plurality of operation areas are set outside a display area of the image in the screen SC and the indicated position detected by the position detection section 151 is within an operation area, performs a function related to an operation associated with the operation area.

Description

  The present invention relates to a display device that displays an image on a display surface and a control method for the display device.

  Conventionally, when a specific position of an image displayed by a display device such as a projector is instructed by an indicator, an apparatus that detects the indicated position and displays a pointer or the like so as to correspond to the detected position is known. (For example, refer to Patent Document 1). In this type of apparatus, when the designated position is detected, for example, a pointer is displayed corresponding to the designated position, and an image indicating the locus of the designated position is drawn and displayed, and displayed on the display surface. The image is controlled.

JP 2004-272433 A

However, in order to control the display device and execute various functions of the display device, it has been necessary to use an operation button provided on the display device body, a remote control for remotely operating the display device, or the like. Therefore, it is necessary for the user to switch between an indicator for controlling the display image and a remote controller for controlling the display device, and improvement in operability has been desired.
An object of the present invention is to solve the problems of the conventional technology described above and to improve operability when executing various functions of a display device.

In order to achieve the above object, the present invention provides a display means for displaying an image on a display surface, a detection means for detecting an operation position on the display surface, and a plurality of operations outside an image display area on the display surface. Control means for executing a function related to an operation associated with the operation area when the area is set and the operation position detected by the detection means is within the operation area. And
According to this configuration, it is possible to operate the function of the display device corresponding to the operated area by the operation in the operation area on the display surface, and the operability of the operation for executing various functions of the display device. Can be improved.

According to the present invention, in the display device, image data supplied from a plurality of image supply units including an external device is displayed on each of the plurality of display areas provided on the display surface by the display means. A display control means is provided, and a plurality of the operation areas are associated with each of the display areas.
According to this configuration, when displaying image data supplied from a plurality of image supply units in a plurality of display areas, various functions of the display device for each image are executed by operations in the operation area on the display surface. It is possible to improve the operability.

In the display device according to the aspect of the invention, when an operation that spans the plurality of operation areas is detected by the detection unit, a function associated with the operation that spans the plurality of operation areas is executed. Features.
According to this configuration, various functions of the display device can be executed by operations over a plurality of operation areas. For this reason, various functions can be executed in association with the operation in the operation area, and the operability can be further improved.

The display device may further include an imaging unit that captures a range including the display region, the detection unit detects the operation position based on a captured image of the imaging unit, and the operation region is The image pickup unit is set within a shootable area.
According to this configuration, the operation position for the displayed image can be detected more quickly and accurately.

In the display device according to the aspect of the invention, the control unit may switch the image displayed in the display region to another image when an operation on the operation region is detected by the detection unit. A freeze function that freezes the displayed image, a mute function that stops the display of the image, a zoom function that enlarges or reduces the displayed image, a function that changes the display position of the image displayed in the display area, And at least one of a function of switching between a mode for processing the information indicating the operation position detected by the detection means inside the display device and a mode for outputting the information to the outside. .
According to this configuration, various functions of the display device can be operated by operating the operation area on the display surface without operating the operation panel or the remote control of the display device, thereby improving operability. Can do.

In order to achieve the above object, the present invention provides a display device control method for displaying an image on a display surface, wherein an operation position on the display surface is detected, and an outside of a display area of the image on the display surface. When a plurality of operation areas are set and the detected operation position is within the operation area, a function related to an operation associated with the operation area is executed.
According to this configuration, it is possible to operate the function of the display device corresponding to the operated area by the operation in the operation area on the display surface, and the operability of the operation for executing various functions of the display device. Can be improved.

  According to the present invention, it is possible to operate the function of the display device corresponding to the operated region by the operation in the operation region on the display surface, and the operability of the operation for executing various functions of the display device. Can be improved.

It is a figure which shows the structure of the display system which concerns on embodiment of this invention. It is a functional block diagram of each part which comprises a display system. It is a flowchart which shows operation | movement of a display system. It is a figure explaining the operation | movement which controls the display corresponding to the example of arrangement | positioning of the operation area | region on a screen, and operation, (A) shows the example regarding a display switching function, (B) shows the example regarding a source switching function, (C) shows an example relating to the zoom function. It is a figure explaining the operation | movement which controls the display corresponding to the example of arrangement | positioning of the operation area | region on a screen, and operation, (A) shows the example regarding a horizontal scroll function, (B) shows the example regarding a vertical scroll function, (C) shows an example related to the mute function, (D) shows an example related to the network connection standby function, and (E) shows an example related to the operation lock / release function.

Embodiments to which the present invention is applied will be described below with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration of a display system 10 using a projector 11 according to an embodiment.
The projector 11 as a display device is connected to a PC (Personal Computer) 13 as an image supply unit by an image signal cable or the like. The PC 13 has a monitor 144 and outputs, for example, image data of the same image as the image being displayed on the monitor 144 to the projector 11.
The projector 11 projects a display image on a screen SC as a projection surface (display surface) based on the input image data. The image data input from the PC 13 may be either moving image (video) data or still image data, and the projector 11 can project both moving images and still images based on the input image data. The projector 11 is connected to the PC 13 via a control signal transmission communication line such as a USB cable or a LAN cable, separately from the image signal cable or the like for transmitting image data, and is connected to the PC 13 via this communication line. Send and receive control data. It is also possible to use a wireless communication line as a control signal transmission communication line. Alternatively, the image data and the control data may be superimposed and transmitted on a single cable connecting the PC 13 and the projector 11.
As a projection surface (display surface), a wall surface itself may be used in addition to a curtain or a flat plate installed on a wall surface or a floor surface.
As shown in FIG. 1, the maximum range (region) in which the projector 11 can project an image is set as a displayable region 5 on the screen SC.

Although not shown, the projector 11 can be connected to an image supply device such as a DVD player or a video recorder in addition to a plurality of PCs 13 as an image supply unit. Further, the projector 11 may be configured to incorporate an image supply unit. In other words, the image data projected by the projector 11 may be generated by a circuit built in the projector 11.
The projector 11 provides a single display area in the displayable area 5 and displays an image based on image data input from one image supply apparatus, and a plurality of display areas 6 (see FIG. 4). (Hereinafter, referred to as display areas 6A and 6B), it is possible to execute multi-screen display in which image data input from a plurality of image supply devices is displayed in each of the plurality of display areas 6A and 6B.

In the display system 10, it is possible to perform a position instruction operation using the indicator 70 on the screen SC. The indicator 70 is a pen-type device, for example, and the user uses the shaft portion 71 of the indicator 70 in his hand and presses the tip against the screen SC. An operation switch 72 that detects a pressing operation is provided at the tip of the indicator 70, and the operation switch 72 is turned on when the user presses the tip of the indicator 70 against the screen SC.
The projector 11 has a function of detecting the tip position of the indicator 70 as the indication position 70A. The projector 11 can process control data indicating the coordinates of the detected designated position 70A by a circuit inside the projector 11 and perform processing such as drawing an image based on the detected coordinates of the designated position 70A, for example. . The projector 11 can also output control data indicating the coordinates of the designated position 70A to the PC 13.
In addition, when the user performs an operation of pressing the tip of the indicator 70 against the screen SC on the screen SC, the projector 11 executes various functions such as a source switching function, a freeze function, a mute function, and a zoom function. This operation will be described later.

FIG. 2 is a block diagram illustrating a functional configuration of the display system 10.
Based on the image data input from the PC 13, the projector 11 projects an image processing unit 110 that performs image processing for displaying an image on the screen SC, and an image processed by the image processing unit 110 on the screen SC. A projection unit (display means) 3, a position detection unit (position detection means) 150 that detects the indicated position 70 </ b> A of the indicator 70 on the screen SC, and a control unit 103 that controls these parts are provided.
The control unit 103 includes a CPU, a non-volatile memory, a RAM, and the like (not shown). The control unit 103 reads out and executes a control program 105A stored in the storage unit 105 connected to the control unit 103, and controls each unit of the projector 11. . Further, the control unit 103 executes the control program 105A stored in the storage unit 105, so that the shooting range (view angle) of the position detection unit 150, that is, the position in the shot image data, the position on the actual projection area 11B, and Then, calibration for specifying the correspondence with the position on the image drawn by the image processing unit 113 is executed. The control unit 103A obtains a coordinate conversion parameter used by the coordinate calculation unit 159 based on the correspondence between the position on the captured image specified by the calibration and the position on the actual projection area 11B. The coordinate conversion parameters include data that associates the coordinates on the image drawn by the image processing unit 113 with the coordinates obtained on the captured image data. The coordinate calculation unit 159 can convert the coordinates obtained on the captured image data into the coordinates on the image drawn by the image processing unit 113 based on the coordinate conversion parameters. Calibration is basically performed by the projector 11 alone. The projector 11 acquires coordinate conversion parameters, and manually or automatically associates the coordinate system of the actual projection area with the coordinate system of the captured image. I do. When calculating the coordinates, the projector 11 converts the position on the captured image into the position on the actual projection area based on the acquired coordinate conversion parameter. The projector 11 converts the coordinates on the image data input from the PC 13 and the coordinates on the actual projection area based on the resolution of the image input from the PC 13 and information on the display position on the actual projection area. . The storage unit 105 is configured by a magnetic or optical recording device or a semiconductor storage element, and stores various programs including a control program 105A and data such as various setting values.

The control unit 103 is connected with an operation panel 41 as an operation unit and a remote control light receiving unit 45 that detects an operation of a remote control as an operation unit.
The operation panel 41 includes various switches and indicator lamps, and is disposed in an exterior housing (not shown) of the projector 11. When a switch on the operation panel 41 is operated, an operation signal corresponding to the operated switch is output to the control unit 103.
The remote control light receiving unit 45 receives an infrared signal transmitted in response to a button operation by a remote control (not shown) used by a user as an operator who operates the projector 11. The remote control light receiving unit 45 demodulates and decodes the infrared signal received from the remote control, and outputs an operation signal indicating an operation on the remote control to the control unit 103.
The operation of the projector 11 can be executed by the PC 13 in addition to the indicator 70, the operation panel 41, and the remote controller. In this case, the PC 13 outputs control data for operating the projector 11 and functions as an operation unit.
The control unit 103 detects a user operation based on operation signals input from the operation panel 41 and the remote control light receiving unit 45, and controls the projector 11 according to the operation.

The projection unit 30 includes an illumination optical system 31, a light modulation device 32 (light modulation unit), and a projection optical system 33. The illumination optical system 31 includes a light source including a xenon lamp, an ultra high pressure mercury lamp, an LED (Light Emitting Diode), and the like. The illumination optical system 31 also includes a reflector and auxiliary reflector that guides light emitted from the light source to the light modulation device 32, a lens group (not shown) for enhancing the optical characteristics of the projection light, a polarizing plate, or light emitted from the light source. A dimming element or the like for dimming light may be provided.
The light modulation device 32 modulates the light from the illumination optical system 31 to form image light. In the present embodiment, a case where the light modulation device 32 is configured using a transmissive liquid crystal panel will be described as an example. In this configuration, the light modulation device 32 has three liquid crystal panels corresponding to the three primary colors of RGB, and the light emitted from the illumination optical system 31 is separated into three color lights of RGB, and each liquid crystal corresponds to each color light. Incident on the panel. The color light modulated by passing through each liquid crystal panel is combined by a combining optical system such as a cross dichroic prism and emitted to the projection optical system 33.

The projection optical system 33 includes a lens or a lens group that performs enlargement / reduction and focus adjustment of an image to be projected, a zoom adjustment motor that adjusts the degree of zoom by driving the lens, and a focus adjustment motor that performs focus adjustment. Etc.
The projection unit 3 includes a projection optical system drive unit 121, a light modulation device drive unit 119, and a light source drive unit 117 together with the projection unit 30. The projection optical system drive unit 121 drives each motor included in the projection optical system 33 according to the control of the display control unit 107 of the image processing unit 110. The light modulation device driving unit 119 performs drawing by driving the light modulation device 32 based on the image signal output from the display control unit 107. The light source driving unit 117 drives a light source included in the illumination optical system 31 according to the control of the control unit 103.

The image processing unit 110 includes an image input unit 104 connected to the PC 13. The image input unit 104 is an interface through which various image supply devices including the PC 13 input image data. For example, a general-purpose interface such as a DVI interface, a USB interface, a LAN interface, or an HDMI (registered trademark) interface can be used. In addition, image data may be input to the image input unit 104 using wireless communication. The image input unit 104 may include an A / D conversion circuit that converts an analog video signal into digital image data and an analog video signal input terminal such as a VGA terminal. Further, the image input unit 104 may include a DisplayPort (trademark) interface. In this case, the projector 11 can be connected to the DisplayPort included in the PC 13 or a portable device having the same function as the PC 13.
The image processing unit 110 develops the image in the frame memory 115 according to the control of the display control unit 107 that processes the image data input via the image input unit 104 and the display control unit 107, and the projection unit 30 projects the image. An image processing unit 113 that generates an image is provided. The image processing unit 113 functions as an image supply unit built in the projector 11.

The display control unit 107 determines the format (frame rate, resolution, compression state) of image data input via the image input unit 104 and performs processing necessary for displaying the display image on the light modulation device 32. And the image processing unit 113 is controlled to execute the process. The processing executed here is, for example, frame rate conversion, interlace / progressive conversion, resolution conversion, compressed image data expansion processing, stereoscopic image data format conversion, and the like. The image processing unit 113 expands the image data input to the image input unit 104 in the frame memory 115 under the control of the display control unit 107, and executes various processes as described above. The image processing unit 113 generates an image signal of a predetermined format for displaying the image based on the processed image drawn in the frame memory 115 and outputs the image signal to the display control unit 107. The display control unit 107 outputs the image signal generated by the image processing unit 113 to the light modulation device driving unit 119.
The image processing unit 113 can also perform various image processing such as keystone correction, color tone correction corresponding to the color mode, and image enlargement / reduction processing under the control of the display control unit 107. That is, the control unit 103 causes the display control unit 107 to execute keystone correction and display image enlargement / reduction processing based on an operation signal input from the operation panel 41 or the remote control light receiving unit 45. The display control unit 107 calculates various parameters necessary for keystone correction and display image enlargement / reduction processing, and controls the image processing unit 113 to execute keystone correction and display image enlargement / reduction processing.

The indicator 70 operated by the user includes the above-described operation switch 72 and a transmission unit 74 that outputs a signal indicating the operation state (ON / OFF) of the operation switch 72. For example, the transmission unit 74 transmits an infrared signal indicating ON / OFF of the operation switch 72 by a method compliant with the IrDA standard.
The position indicated by the pointer 70 is detected by the position detection unit 150 as described above. The position detection unit 150 may be configured to detect one type of indicator 70, or a plurality of types of indicators 70 such as a pen-type operation device and a user's finger. The structure which can be detected may be sufficient. When the position detection unit 150 can detect a plurality of types of indicators 70, the position detection unit 150 may be configured to detect the types of the indicators 70.
The position detection unit 150 detects the operation state of the operation switch 72 based on the signal transmitted by the transmission unit 74. Further, the position detection unit 150 may be configured to detect whether or not the tip of the indicator 70 is in contact with the screen SC and detect a position indication operation by the indicator 70.

The detection of the indicator 70 by the position detection unit 150 can employ various methods. For example, the indicator 70 may have a light emitting unit (not shown), and the light emitting unit may emit light when the tip of the indicator 70 contacts the screen SC. Further, the position detection unit 150 may analyze the light emission position of the light emitting unit of the indicator 70 on the captured image data of the imaging unit 153, which will be described later, and calculate the coordinates of the instruction position 70A of the indicator 70. good. According to this configuration, it is possible to detect contact / non-contact of the pointing position 70A of the indicator 70 and the screen SC of the indicator 70. The light emitted from the light emitting portion of the indicator 70 may be visible light, or may be invisible light such as infrared light. When the light emitting unit of the indicator 70 emits invisible light, a configuration in which a visible light cut filter that allows only infrared light to pass therethrough may be provided in front of the imaging unit 153.
In addition to the configuration in which the light emitting unit emits light when the tip contacts the screen SC, the indicator 70 blinks when the tip is in contact with the screen SC and when the tip is not in contact. (Light emission / non-light emission) The structure which changes a pattern may be sufficient. According to this configuration, it is possible to detect contact / non-contact of the pointing position 70A of the indicator 70 and the screen SC of the indicator 70. Further, according to this configuration, it is possible to detect the hovering state of the indicator 70 that moves on the screen SC while the tip of the indicator 70 is not in contact with the screen SC.

The position detection unit 150 is a coordinate that calculates the coordinates of the position detection unit 151 including the imaging unit 153, the imaging control unit 155, the reception unit 154, and the position detection processing unit 157, and the designated position 70A detected by the position detection unit 151. And a calculation unit 159.
The imaging unit 153 is a digital camera mounted on the projector 11 so as to capture the direction in which the projection optical system 33 projects image light. The angle of view taken by the imaging unit 153 is the imaging area 7 including the displayable area 5 on the screen SC. The imaging unit 153 performs imaging in accordance with the control of the imaging control unit 155, and outputs captured image data. The imaging control unit 155 controls the imaging unit 153 to execute imaging in accordance with the control of the control unit 103. When the imaging unit 153 has mechanisms for adjusting zoom magnification, focus, and aperture during shooting, the shooting control unit 155 controls these mechanisms to execute shooting under preset conditions. After shooting, the shooting control unit 155 acquires the shot image data output by the imaging unit 153 and outputs it to the position detection processing unit 157. The captured image data output from the imaging unit 153 may be expressed in a format such as RGB or YUV, or may represent only a luminance component. The imaging unit 153 may be configured to capture light other than visible light (for example, infrared light). Further, the shooting control unit 155 may output the shot image data output from the imaging unit 153 as it is to the position detection processing unit 157, and adjusts the resolution, converts it into a predetermined file format (JPEG, BMP, etc.), etc. May be output to the position detection processing unit 157.

The receiving unit 154 receives the radio signal transmitted by the transmitting unit 74 of the indicator 70, detects the operation state of the operation switch 72, and outputs data indicating the detection result to the position detection processing unit 157. The position detection processing unit 157 detects the pointing position 70A of the pointer 70 based on the captured image data of the imaging unit 153, and acquires the operation state of the operation switch 72 based on the data input from the receiving unit 154.
In addition, when the imaging unit 153 receives infrared light to perform shooting and the transmission unit 74 is configured to transmit an infrared signal, the infrared signal transmitted by the transmission unit 74 is based on the captured image data. By detecting the position detection processing unit 157, the receiving unit 154 can be omitted.

The position detection processing unit 157 detects the position of the tip of the indicator 70, that is, the indicated position 70A by analyzing the captured image data input from the imaging control unit 155. In the present embodiment, the imaging unit 153 performs imaging at predetermined time intervals under the control of the imaging control unit 155, and the position detection processing unit 157 is based on captured image data input from the imaging control unit 155 at predetermined time intervals. The indication position 70A is detected, and the indication position 70A when the operation switch 72 is turned on is determined as the indication position 70A when the operation switch 72 is operated.
The coordinate calculation unit 159 calculates the coordinates of the designated position 70A detected by the position detection processing unit 157. The coordinates calculated by the coordinate calculation unit 159 are coordinates in the captured image data at the designated position 70A, and are coordinates on a coordinate axis virtually provided on the display image of the screen SC. The coordinates in the captured image data are affected by various factors such as the distance between the projector 11 and the screen SC, the zoom ratio in the projection optical system 33, the installation angle of the projector 11, and the distance between the imaging unit 153 and the screen SC. On the other hand, since the positional relationship between the angle of view of the imaging unit 153 and the projection range of the projection optical system 33, the imaging magnification of the imaging unit 153, the zoom rate in the projection optical system 33, and the like are known, the coordinate calculation unit 159 The correspondence relationship between the data and the displayable area 5 displayed on the screen SC can be calculated. By this processing, the coordinate calculation unit 159 calculates the coordinates of the designated position 70A in the display image of the screen SC, and outputs the coordinate data. In addition, the coordinate calculation unit 159 adds data indicating that the operation switch 72 is ON to the coordinate data of the designated position 70A when the position detection processing unit 157 detects the ON operation of the operation switch 72, and outputs it. To do.

The coordinate data output from the coordinate calculation unit 159 is input to the coordinate conversion unit 160. The coordinate conversion unit 160 converts coordinate data according to the control of the control unit 103. When the coordinate data is output to the PC 13, the coordinate conversion unit 160 converts the coordinate data input from the coordinate calculation unit 159 into coordinate data indicating the coordinates in the frame of the image data input to the image input unit 104 by the PC 13. This conversion process is executed based on the resolution of the image data input to the image input unit 104 by the PC 13 and the process performed on the image data by the image processing unit 113. When the coordinate data is output to the image processing unit 110, the coordinate conversion unit 160 converts the coordinate data input from the coordinate calculation unit 159 into coordinate data indicating the coordinates in the frame of the image drawn by the image processing unit 113. To do. That is, the coordinate conversion unit 160 can perform conversion into coordinates corresponding to the PC 13 that is an externally connected image supply unit and the image processing unit 110 that is an image supply unit built in the projector 11. The coordinates are converted into coordinates corresponding to the output destination image supply unit.
Examples of information necessary for the process of converting coordinates by the coordinate conversion unit 160 include, for example, the resolution of the image data of the image drawn by the image processing unit 113, the aspect ratio, the display size on the liquid crystal display panel of the light modulation device 32, and the light modulation. There is information such as a position where an image is drawn on the liquid crystal display panel of the device 32. These pieces of information are output from the image processing unit 113 to the coordinate conversion unit 160 in response to control by the control unit 103 or a request from the coordinate conversion unit 160.
When the coordinate conversion unit 160 converts the coordinates corresponding to the image processing unit 110, the coordinate conversion unit 160 outputs the converted coordinate data to the image processing unit 113. In addition, when the coordinate conversion unit 160 converts the coordinates corresponding to the PC 13, the coordinate conversion unit 160 outputs the converted coordinate data to the output unit 101. That is, the converted coordinate data is output to the image supply unit designated by the control unit 103 during the conversion process.

The output unit 101 is an interface that outputs the converted coordinate data output from the coordinate conversion unit 160 to the PC 13. For example, the output unit 101 includes a general-purpose interface such as a USB interface, a LAN interface, or IEEE1394, and performs wired communication and wireless communication. Either of them may be used. Here, the functions of both the output unit 101 and the image input unit 104 may be realized by integrating the image input unit 104 and the output unit 101 and physically using one interface (for example, a USB interface). A plurality of PCs 13 are connected to the output unit 101, and the output unit 101 selects one or more PCs 13 under the control of the control unit 103 and outputs coordinate data. Normally, the output unit 101 selects the PC 13 that supplies image data to the image input unit 104. When there are a plurality of PCs 13 that supply image data, the output unit 101 selects one or more PCs 13 as an output destination from the PCs 13 according to the control of the control unit 103.
Coordinate data output from the output unit 101 to the PC 13 is input as data similar to coordinate data output from a pointing device such as a mouse, trackball, digitizer, or pen tablet in each PC 13.
Further, the output unit 101 may be connected to the image processing unit 113 included in the image processing unit 110, and the converted coordinate data output from the coordinate conversion unit 160 may be output to the image processing unit 110.

When the PC 13 handles the coordinate data output from the output unit 101 in the same manner as the coordinate data output by the general-purpose pointing device, a general-purpose device driver program corresponding to these general-purpose pointing devices can be used. Such a general-purpose device driver program is normally installed in advance as a part of the OS (operating system) of the PC 13, and thus can be used without installing the device driver program.
Thus, when using a general-purpose device driver program, there is an advantage that a dedicated device driver program is not required, but information that can be exchanged between the projector 11 and the PC 13 is determined by the specifications of the general-purpose device driver program. It is limited to the range. Therefore, a dedicated device driver program corresponding to the projector 11 may be installed in the PC 13 and the coordinate data output from the output unit 101 may be processed by this device driver program. In this case, information that can be exchanged between the projector 11 and the PC can be arbitrarily set according to the specifications of the dedicated device driver program.

The PC 13 draws, for example, a line or a figure based on the coordinate data input from the output unit 101, and generates new image data by superimposing the drawn line or figure on the image being output to the projector 11. The image data is output to the projector 11.
Based on the coordinate data input from the coordinate conversion unit 160 or the output unit 101, the image processing unit 113 draws, for example, a line or a figure on the display image developed in the frame memory 115, and after the drawing An image signal for displaying the image is generated and output to the light modulator driving unit 119.
As a result, in the display system 10, when the user performs a position instruction operation by operating the indicator 70, a figure or the like is drawn and displayed over the image being displayed on the screen SC corresponding to the operated position. The

Next, the operation of the projector 11 will be described with reference to FIGS.
FIG. 3 is a flowchart showing the operation of the projector 11 when an operation for executing the function of the projector 11 is performed by the indicator 70.
When the position detection processing unit 157 detects that the operation state of the operation switch 72 of the indicator 70 is ON (step S1), the position detection processing unit 157 analyzes the captured image data input from the imaging control unit 155 and uses the indicator 70. The designated position 70A is confirmed (step S2), and information regarding the confirmed designated position 70A is output to the control unit 103.

The control unit 103 determines whether or not the designated position 70A determined by the position detection processing unit 157 is within the display area where the image is displayed (step S3). When the control unit 103 determines that the designated position 70A is within the display region (step S3: Yes), the coordinate calculation unit 159 determines the coordinates of the designated position 70A determined by the position detection processing unit 157 as described above. The coordinates of the input image data of the PC 13 are converted by the function of the coordinate conversion unit 160 and the converted coordinate data is output from the output unit 101 to the PC 13 (step S4). Execute the process.
On the other hand, when it is determined that the designated position 70A is outside the display area (step S3: No), the control unit 103 determines whether the designated position 70A is within the operation area arranged outside the display area. (Step S5). If the control unit 103 determines that the designated position 70A is not within the operation region (step S5: No), the operation ends. Further, when the control unit 103 determines that the designated position 70A is within the operation area (step 5: Yes), the control unit 103 executes a function of the projector 11 that is set in advance in association with the operation area that overlaps the designated position 70A ( Step S6).

4A and 4B are diagrams for explaining an example of the arrangement of the operation area on the screen SC and an operation for controlling the display corresponding to the operation. FIG. 4A shows an example related to the display switching function, and FIG. 4B shows a source switching function. (C) shows an example related to the zoom function.
In the example illustrated in FIG. 4A, the projector 11 performs single screen display, and an image based on image data input from the PC 13 is displayed in the display area 6 arranged in the displayable area 5. As described above, the displayable area 5 is an area in which an image can be displayed by the projection optical system 33. More specifically, it is the maximum area where the projection optical system 33 can display an image, or the maximum area where an image after trapezoidal distortion correction or pincushion distortion correction can be displayed. The size of the displayable area 5 varies depending on the zoom rate of the projection optical system 33, the distance from the screen SC to the projection optical system 33, the area that can be used for display on the liquid crystal panel of the light modulation device 32, and the like. The displayable area 5 can be determined by detecting an image from the captured image data of the imaging unit 153.
A display area 6 for displaying an image is arranged in the displayable area 5. In the example of FIG. 4A, one displayable area 5 is arranged in the display area 6 when executing single screen display for displaying one image on the screen SC. FIG. 4A shows an example in which the entire displayable area 5 is the display area 6. In addition, when executing multi-screen display in which images based on image data supplied from a plurality of PCs 13 are displayed side by side on the screen SC, a plurality of display areas 6A are displayed in the display area 6 as shown in FIG. , 6B are arranged. Depending on the aspect ratio of the display areas 6A and 6B, a non-display area 6C in which no image is displayed in the displayable area 5 is generated. The non-display area 6C can be generated not only when the multi-screen display shown in FIG. 4B is executed but also when the single-screen display is executed.

An operation area 80 is arranged around the displayable area 5. The operation area 80 includes lower edge operation areas 81A and 81B disposed below the displayable area 5, side edge operation areas 82A and 82B disposed on the left and right sides of the displayable area 5, and above the displayable area 5. Upper edge operation areas 84A and 84B, lower corner operation areas 83A and 83B, and upper corner operation areas 85A and 85B arranged outside the corners of the display area 6. The operation area 80 is not actually displayed on the screen SC but is virtually set by the control unit 103. The operation areas constituting the operation area 80 are arranged so as not to overlap each other and not to overlap the displayable area 5, and the boundary between the displayable area 5 and the operation area 80 is included in the operation area 80. Absent. Further, the entire operation area 80 is within a range in which the projector 11 can detect the designated position 70 </ b> A of the indicator 70, that is, inside the imaging area 7 of the imaging unit 153. In the example of FIG. 4A, the entire imaging area 7 is an operation area 80 and a display area 6.
In the example of FIG. 4A, when the position indicating operation of the indicator 70 is performed inside the imaging area 7, the indicated position 70A is either on the displayable area 5 or the operation area 80. Belonging to. In addition, each operation area | region which comprises the operation area | region 80 may be arrange | positioned separately, and the displayable area | region 5 and the operation area | region 80 may be distant.
In addition, when the non-display area 6C occurs as described above, the operation area 80 is disposed outside the non-display area 6C. In this case, a guide (for example, a straight line or a point) may be displayed on the periphery of the non-display area 6C so that the user can easily recognize the boundary between the operation area 80 and the non-display area 6C.

The function of the projector 11 can be assigned to each operation area of the operation area 80. When the designated position 70A belongs to any one of the operation areas, the control unit 103 executes a function assigned to the operation area.
In the example of FIG. 4A, the lower edge operation areas 81A and 81B are associated with a display switching function that alternately switches between single screen display and multi-screen display. When any one of the lower edge operation areas 81A and 81B is operated by the indicator 70 during the execution of the single screen display, the control unit 103 switches the display state to the multi-screen display. Further, when the lower edge operation areas 81A and 81B are operated during execution of multi-screen display, switching to single-screen display is performed. During multi-screen display, the lower edge operation area 81A is associated with one display area 6A, and the lower edge operation area 81B is associated with the other display area 6B. For this reason, when the lower edge operation area 81A is operated, the image being displayed in the display area 6A is displayed on a single screen. Similarly, when the lower edge operation area 81B is operated, the image being displayed in the display area 6B is displayed on a single screen.
In this way, by tapping the operation area 80 with the indicator 70, the single screen display and the multi-screen display can be switched alternately. Further, during multi-screen display in which images are displayed in a plurality of display areas, the plurality of operation areas constituting the operation area 80 can be associated with any one of the display areas. Thereby, when the designated position 70A overlaps the operation area, the display area corresponding to the operation area is specified, and the function for the image being displayed in the specified display area is executed. That is, not only a function to be executed can be specified by a single operation by the indicator 70, but also an image to be executed for the function can be specified.

Further, as shown in FIG. 4B, the operation area can be associated with a source switching function for switching an image supply device that supplies image data to the projector 11. In this example, the source switching function is assigned to the lower edge operation areas 81A and 81B, and the flick operation of the indicator 70 (operation to slide the indicator 70 sideways) is performed at a position overlapping the lower edge operation area 81B. In this case, the PC 13 that supplies image data to the display area 6B as the image supply device is switched to another PC 13. For example, when a flick operation is performed in the lower edge operation area 81B while an image based on the image data output from the PC 13A in FIG. 2 is displayed in the display area 6B, an image based on the image data output from the PC 13B is displayed in the display area 6B. 6B.
In this example, each of the operation areas constituting the operation area 80 is associated with a plurality of display areas 6A and 6B. For example, the lower edge operation area 81A corresponds to the display area 6A, and the lower edge operation area 81B corresponds to the display area 6B. Of course, other operation areas can be associated with the display areas 6A and 6B.

As shown in FIG. 4C, the operation area can be associated with an operation of a zoom function for enlarging / reducing an image displayed by the projector 11.
In this example, a zoom function is assigned to the lower edge operation areas 81A and 81B. The zoom function requires an operation for specifying whether to enlarge or reduce, an operation for specifying an enlargement ratio or a reduction ratio, and the like. In this example, enlargement or reduction is performed depending on the operation mode of the indicator 70. You can specify the rate / reduction rate.
Here, as an example of the operation mode, an operation using two indicators 70 and 70 is illustrated. When the operation area is touched with the two indicators 70 and the two indicators 70 and 70 are operated so as to be close (to narrow the interval), the zoom function reduces the image, and the two indicators 70 and 70 are separated (the interval is set to be small). When the operation is performed, the image is enlarged by the zoom function. The reduction rate and the enlargement rate correspond to the amount of change in the distance between the two indicators 70 and 70.

In the example of FIG. 4C, the projector 11 performs multi-screen display, the lower edge operation area 81A corresponds to the display area 6A, and the lower edge operation area 81B corresponds to the display area 6B. When the lower edge operation area 81A is operated, the zoom function of the image in the display area 6A is executed, and when the lower edge operation area 81B is operated, the zoom function of the image in the display area 6B is executed. Further, when an operation that extends over the lower edge operation area 81A and the lower edge operation area 81B is performed, both the image of the display area 6A and the image of the display area 6B are enlarged or reduced.
In the example of FIG. 4C, the image of the display area 6A is enlarged by operating the two indicators 70, 70 in the lower edge operation area 81A during multi-screen display. Further, when an operation is performed so that the indicator 70 on the lower edge operation area 81A is separated from the indicator 70 on the lower edge operation area 81B, both the image of the display area 6A and the image of the display area 6B are displayed. Has been expanded.
As described above, the projector 11 can execute a function assigned in advance according to an operation on the operation area, and can specify an image to be executed by selecting the operation area during multi-screen display. Further, detailed parameters regarding the execution of the function can be specified by the operation mode of the indicator 70.
The operation mode of the indicator 70 is not limited to the above-described operation by the plurality of indicators 70, and includes, for example, a combination of a plurality of tap operations. Further, when performing a zoom function of an image and performing an operation of enlarging the image in the display area 6A during multi-screen display, the image in the display area 6B is reduced accordingly, and the display area The range of the operation area corresponding to each of 6A and the display area 6B may be changed according to the size of the image.

FIG. 5 is a diagram for explaining an example of the arrangement of the operation area on the screen SC and an operation for controlling the display corresponding to the operation on the operation area. FIG. 5A shows an example of the horizontal scroll function. 5B shows an example related to the vertical scroll function, FIG. 5C shows an example related to the mute function, FIG. 5D shows an example related to the network connection standby function, and FIG. 5E shows an operation lock. An example regarding the / release function is shown.
In the example shown in FIG. 5A and FIG. 5B, the scrolling (display movement) function of the image displayed in the display area 6 (the position of the image displayed in the display area 6 is moved relative to the operation area). Function) is assigned. Specifically, the horizontal scroll function is associated with the lower edge operation areas 81A and 81B, and the vertical scroll function is associated with the side edge operation areas 82A and 82B. As shown in FIG. 5A, an image displayed in the display area 6A is moved with the movement of the indicator 70 by performing an operation of moving the indicator 70 touched in the lower edge operation region 81A to the left and right. To move left and right. Further, as shown in FIG. 5B, an image displayed in the display area 6B is moved along with the movement of the indicator 70 by the operation of moving the indicator 70 touched in the side edge operation region 82B up and down. Moved up and down. In this embodiment, the vertical image movement and the horizontal image movement are assigned to different operation areas. However, the present invention is not limited to this. A configuration in which movement of an image in a horizontal direction and an oblique direction is assigned may be used.

  In the example shown in FIG. 5C, a mute function for deleting the display image of the projector 11 is associated with the operation area. Specifically, when the touch operation by the indicator 70 is performed in the lower corner operation area 83A, the projection of the image light by the projection unit 30 is stopped, and the image being displayed in the display area 6A is erased (display is stopped). . This function is realized by a method in which the display of the corresponding region in the liquid crystal panel of the light modulation device 32 is all black, or a method in which the light emitted from the illumination optical system 31 is blocked. When the mute function is executed, in addition to displaying all black in the display area, a blue image may be displayed, or an image indicating that the mute state is displayed.

  In the example shown in FIG. 5D, a network connection standby function for setting the network connection between the projector 11 and the PC 13 in a standby state is associated with the operation area. When a touch operation by the indicator 70 is performed in the lower corner operation area 83A, the connection state with the PC 13 that supplies the image displayed in the display area 6A is switched to the standby state. In the standby state, no image is input from the PC 13, and therefore no image is displayed in the display area 6A. Therefore, in order to facilitate reconnection with the PC 13 or other image supply device, a two-dimensional code including network connection information may be displayed in the display area 6A as shown in FIG. 5D. . Further, the projector 11 may display specific connection information necessary for connection with the projector 11 (for example, the IP address and SSID of the projector). Further, the projector 11 may send out radio waves necessary for network connection via a wireless communication interface.

In the example shown in FIG. 5E, an operation lock / release function that locks an operation on a displayed image is associated with an operation that straddles a plurality of operation areas. Specifically, the operation lock function of the display area 6A is assigned to an operation in which the indicator 70 passes through the lower corner operation area 83A, and the operation of the display area 6B in response to an operation through the lower corner operation area 83B. The operation lock function is assigned. When the indicator 70 moves from the side edge operation area 82A through the lower corner operation area 83A to the lower edge operation area 81A, the operation on the image displayed in the display area 6A is locked, and the operation is temporarily disabled. Become. When the same operation is performed again, the operation set for the display area 6A is unlocked and can be operated. Since these operations are characteristic, there is no possibility that the user unintentionally locks / unlocks accidentally, and both improvement in operability and certainty of operation can be achieved.
In addition, for example, a transition to the password lock state in which the input video is not displayed and release can be assigned to an operation of touching the upper corner operation area 85A and subsequently touching the lower corner operation area 83A. This password lock state is used for theft prevention of the projector 11 and can be canceled by either inputting a regular password by operating the operation panel 41 or the remote control or performing the above operation again.

The projector 11 is not limited to the example described above, and the projector 11 processes information indicating the operation position of the indicator 70 detected by the position detection unit 150 inside the projector 11, and the projector 11 executes processing based on the coordinates of the operation position. The interactive mode and the PC interactive mode in which information indicating the operation position of the indicator 70 detected by the position detection unit 150 is output to the external PC 13 and the PC 13 executes processing based on the coordinates of the operation position can be switched. In addition, it may have a mode switching function capable of switching between the PJ interactive mode and the PC interactive mode by an operation on the operation area 80.
For the operation area of the operation area 80, various functions of the projector 11 such as stillness and rotation of images displayed in the display areas 6A and 6B, and OSD display / non-display of the menu screen related to the functions of the projector 11 are provided. Can be assigned. Also, by assigning combinations of operation modes for each operation area, it is possible to assign more complicated operations to prevent erroneous operations, and to make settings and instructions related to the contents of functions to be executed. Thus, the operability of the projector 11 can be further improved. It should be noted that at least two of the operation area, the function executable in the operation area, and the operation for executing the function may be associated with each other by an operation on the menu screen.

  Further, when the designated position 70A is outside the displayable area 5, the projector 11 cannot output the coordinates of the designated position 70A to the PC 13. This is because the coordinates output to the PC 13 are coordinates corresponding to the image data input by the PC 13 and the outside of the display area 6 is outside the image data. Here, when the designated position 70 </ b> A is a position corresponding to one of the operation areas 80, the control unit 103 indicates the control data indicating the operation area or the function of the projector 11 associated with the operation area. Control data may be transmitted to the PC 13. In this case, it is possible to cause the PC 13 to execute some function in response to an operation on the outside of the displayable area 5 at the designated position 70A.

  As described above, the projector 11 according to the embodiment to which the present invention is applied includes the projection unit 3 that displays an image on the screen SC, the position detection unit 150 that detects the indicated position 70A of the indicator 70 on the screen SC, and the screen. When a plurality of operation areas 81A, 81B, 82A, 82B... Are set outside the image display area 6 in the SC and the designated position 70A is within the operation areas 81A, 81B, 82A, 82B. And a control unit 103 that executes a function related to the operation associated with the operation areas 81A, 81B, 82A, 82B,... The function of the projector 11 corresponding to the operation area can be executed. Accordingly, the user can operate various functions of the projector 11 without operating the operation panel 41 of the projector 11 or the remote control of the projector 11. For example, the user performs an operation such as drawing with the indicator 70. In this case, the various functions of the projector 11 can be executed without performing the operation of switching to the remote control, and the operability can be improved. Further, since the operation areas 81A, 81B, 82A, 82B... Are set outside the display area 6, it is not necessary to display an operation switching icon or toolbar in the display area 6, and the input video is blocked by the icon or the like. The drawing range can be expanded without being done.

  In addition, the image processing unit 110 is provided that displays the image data supplied from a plurality of PCs 13 including an external device on each of the plurality of display areas 6A and 6B provided on the screen SC by the projection unit 3, and includes a plurality of operations. The areas 81A, 81B, 82A, 82B... Are associated with the display areas 6A, 6B, respectively. According to this configuration, when performing multi-screen display in which images based on image data supplied from a plurality of PCs 13 are displayed side by side on the screen SC, the operation areas 81A and 81B of the screen SC are displayed for each displayed image. , 82A, 82B,... Are associated with each other, the function of the projector 11 can be executed by operating the indicator 70, and an image to be executed can be designated. Thus, the user can operate the various functions of the projector 11 in detail by operating the indicator 70 without operating the operation panel 41 or the remote control of the projector 11, thereby further improving the operability. Can do.

  Further, according to the projector 11, when an operation of the indicator 70 across the plurality of operation areas 81A, 81B, 82A, 82B... Is detected, the plurality of operation areas 81A, 81B, 82A, 82B are detected. The function associated with the operation across... Can be executed. Further, the projector 11 includes an imaging unit 153 that captures a range including the display areas 6A and 6B, and the position detection unit 150 detects the indicated position 70A of the indicator 70 based on the captured image of the imaging unit 153. The operation area 80 can be set outside the displayable area 5. Thus, the operation area 80 can be provided without reducing the display areas 6A and 6B, and the operability can be improved without affecting the display size of the image.

  The projector 11 also has a source switching function for switching the PC 13 that supplies the images displayed in the display areas 6A and 6B when the operation for the operation area 80 is detected by the position detection unit 150, and the displayed image is stopped. By the freeze function to be performed, the mute function to erase the displayed image, the zoom function to enlarge or reduce the displayed image, the function to change the display position of the image displayed in the display area 6, and the position detection unit 150 Since the user executes at least one of the function of switching the information indicating the detected operation position inside the projector 11 and the mode of outputting the information to the outside, the user can operate the operation panel 41 of the projector 11, Alternatively, without operating the remote control of the projector 11 It can operate the various functions projector 11 has.

In addition, the said embodiment is only an example of the specific aspect to which this invention is applied, This invention is not limited, It is also possible to apply this invention as an aspect different from the said embodiment. For example, the indicator 70 may be a bar-shaped operation device in addition to the configuration of a pen-type operation device, and the position detection processing unit 157 may contact the screen SC with the tip of the bar-shaped operation device. It may be configured to detect whether the position indicating operation is on or off. The indicator 70 may be a pointer such as a finger or a laser pointer. In addition, a plurality of indicators 70 are provided, and different functions are assigned to the respective indicators 70 so that different functions can be operated by the indicators 70 even in the same operation on the same operation area. May be. In addition, by combining with different types of indicators 70, a configuration in which different functions can be operated even with the same operation on the same operation area may be employed.
In the above-described embodiment, the different operation is associated with each of the plurality of operation areas. However, the present invention is not limited to this, and a plurality of operations are assigned to one operation area so that each operation can be identified. It may be configured.

  In the above embodiment, as an example of a switching function for switching an image displayed in the display area 6B or the like to another image, a source switching function for switching an image supply device that supplies image data to the projector 11 will be described. However, the image switching function is not limited to this. For example, an image switching function may be realized by changing the image data supplied to the projector 11 by the image supply device without switching the image supply device that supplies the image data to the projector 11.

In the configuration of the above embodiment, the imaging unit 153 and the imaging control unit 155 included in the position detection unit 150 may be replaced with a digital camera externally connected to the projector 11. The digital camera in this case only needs to execute photographing under the control of the control unit 103 and output photographed image data to the position detection processing unit 157. In addition, a general-purpose interface such as a USB can be used as an interface for connecting the digital camera and the projector 11 and can be easily realized.
In addition, the imaging unit 153 may be configured to be able to image invisible light (such as infrared light). When the invisible light can be imaged, the indicator 70 emits invisible light, A configuration in which the imaging unit 153 captures the invisible light emitted from the indicator 70, and the indicator 70 includes a reflection unit that can reflect the invisible light. The control unit 103 controls the projector 11 to the screen SC. On the other hand, a configuration in which invisible light is projected and invisible light reflected by the reflecting portion of the indicator 70 is imaged by the imaging unit 153 can be employed.

  In the above-described embodiment, the light modulation device 32 is described as an example of a configuration using three transmissive liquid crystal panels corresponding to RGB colors as means for modulating the light emitted from the light source. The present invention is not limited to this. For example, a reflective liquid crystal panel may be used, or a configuration using a digital mirror device (DMD), a combination of a digital mirror device and a color wheel, or the like may be used. May be. Here, when a single liquid crystal panel or DMD is used as the display unit, a member corresponding to a composite optical system such as a cross dichroic prism is unnecessary. In addition to the liquid crystal panel and the DMD, any configuration that can modulate the light emitted from the light source can be used without any problem. Further, it may be a rear projection type projector that projects image light from the back side of the screen SC.

Further, the display device of the present invention is not limited to a projector that projects an image on the screen SC, and the image / image is displayed on a liquid crystal monitor or a liquid crystal television that displays an image / image on a liquid crystal display panel, or a plasma display panel (PDP). Monitor device or television receiver for displaying the image, self-light emission of the monitor device or television receiver for displaying an image / image on an organic EL display panel called OLED (Organic light-emitting diode), OEL (Organic Electro-Luminescence), etc. Various display devices such as a type display device are also included in the image display device of the present invention. In this case, the liquid crystal display panel, the plasma display panel, and the organic EL display panel correspond to display means, and the display screen corresponds to the display surface.
Furthermore, in the configuration of the above embodiment, the configuration in which the position detection unit 150 detects the pointing position 70A by the pointer 70 based on the captured image data has been described as an example. However, the present invention is not limited to this, for example, A configuration in which a pressure-sensitive or capacitive touch panel is provided on a screen SC as a display surface or a display screen in another display method, and the touch of a user's finger or bar as an indicator 70 is detected by this touch panel. It is good. In addition, a method of specifying an indication position by detecting an infrared signal emitted from the indicator, or a method of specifying an indication position by detecting a distance to the indicator by a plurality of devices provided on the screen SC is adopted. May be.

Moreover, each function part of the display system 10 shown in FIG. 2 shows the functional structure implement | achieved by cooperation with hardware and software, Comprising: A specific mounting form is not restrict | limited in particular. Therefore, it is not always necessary to mount hardware corresponding to each function unit individually, and it is of course possible to realize a function of a plurality of function units by one processor executing a program. In addition, in the above embodiment, a part of the function realized by software may be realized by hardware, or a part of the function realized by hardware may be realized by software. In addition, specific detailed configurations of other parts of the display system 10 including the projector 11 and the PC 13 can be arbitrarily changed without departing from the spirit of the present invention.
In addition, the control program 105A stored in the storage unit 105 in the above-described embodiment may be downloaded from another apparatus connected to the projector 11 via a communication network and executed, or may be stored in a portable recording medium. The control program 105A may be recorded, and the above programs may be read from the recording medium and executed.

  DESCRIPTION OF SYMBOLS 3 ... Projection unit (display means), 5 ... Displayable area, 6, 6A, 6B ... Display area, 7 ... Imaging area, 10 ... Display system, 11 ... Projector, 30 ... Projection part, 31 ... Illumination optical system, 32 DESCRIPTION OF SYMBOLS ... Light modulation apparatus, 33 ... Projection optical system, 70 ... Indicator, 70A ... Instruction position, 72 ... Operation switch, 80, 81A, 81B, 82A, 82B, 83A, 83B, 84A, 84B, 85A, 85B ... Operation area , 103 ... control unit (control unit), 103B ... position information determination unit, 110 ... image processing unit (display control unit), 150 ... position detection unit (detection unit), 151 ... position detection unit, 153 ... imaging unit, 157 ... Position detection processing unit, SC ... Screen

Claims (6)

Display means for displaying an image on the display surface;
Detecting means for detecting an operation position on the display surface;
When a plurality of operation areas are set outside the image display area on the display surface and the operation position detected by the detection means is within the operation area, a function related to the operation associated with the operation area And a control means for executing
A display device characterized by that. The display device according to claim 1,
A plurality of operation areas, comprising display control means for displaying image data supplied from a plurality of image supply units including an external device on each of the plurality of display areas provided on the display surface by the display means; Are associated with each of the display areas. The display device according to claim 1 or 2,
A display device that executes a function associated with an operation that spans the plurality of operation areas when the detection unit detects an operation that spans the plurality of operation areas. The display device according to any one of claims 1 to 3,
An imaging unit that captures a range including the display region is provided, the detection unit detects the operation position based on a captured image of the imaging unit, and the operation region is set within a shootable region of the imaging unit. A display device characterized by the above. The display device according to any one of claims 1 to 4,
The control means, when an operation on the operation area is detected by the detection means, a switching function to switch the image displayed in the display area to another image, a freeze function to freeze the displayed image, A mute function for stopping the display of the image, a zoom function for enlarging or reducing the displayed image, a function for changing the display position of the image displayed in the display area, and the operation position detected by the detection means A display device that executes at least one of a function for switching between a mode for processing information indicating the inside of the display device and a mode for outputting the information to the outside. A method of controlling a display device that displays an image on a display surface,
Detecting an operation position on the display surface;
When a plurality of operation areas are set outside the image display area on the display surface and the detected operation position is within the operation area, a function related to an operation associated with the operation area is executed. A control method of a display device characterized by the above.

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