JP2017129697A - Projector and method for controlling projector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a projector capable of appropriately determining settings relating to operations in accordance with types of projection lenses.SOLUTION: A projector 100 includes: a projection part 110 for projecting light onto a screen SC via a light source part 111, a light modulation device 112, and a projection lens 113A; a discrimination part 134 for discriminating whether the projection lens 113A is a normal projection lens or a projection lens different from the normal projection lens; an input reception part 135 for receiving an input of lens information including information indicating that the projection lens 113A is a normal projection lens or information indicating that the projection lens 113A is a projection lens different from the normal projection lens; and a setting part 136 for setting an operation in response to whether the projection lens 113A is a normal projection lens or a projection lens different form the normal projection lens. The input reception part 135 receives an input of lens information when the discrimination part 134 cannot discriminate.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a projector and a method for controlling the projector.

  2. Description of the Related Art Conventionally, there is known a projector in which a projection lens having different optical characteristics such as a normal projection lens, a wide-angle lens, and a telephoto lens can be exchanged and mounted (for example, see Patent Document 1). Patent Document 1 discloses a projector that automatically acquires the type of a mounted projection lens and sets parameters used for image processing according to the acquired type of projection lens.

JP 2005-301317 A

However, there is a concern that the projector described in Patent Document 1 may fail to acquire the type of projection lens. On the other hand, if the configuration is such that the type of the projection lens is manually set every time the projector is activated, the operation burden increases.
Therefore, an object of the present invention is to make it possible to appropriately perform settings related to the operation of the projector in accordance with the type of projection lens.

In order to achieve the above object, the present invention is a projector, and a light source unit that emits first light, and a second light modulated by the first light according to image information. A projection unit that includes a light modulation unit and projects the second light onto a projection surface through a projection lens, and the projection lens is a first projection lens or is different from the first projection lens. A discriminating unit for discriminating whether the projection lens is the second projection lens, and information indicating that the projection lens is the first projection lens, or information indicating that the projection lens is the second projection lens An input receiving unit that receives input of lens information including, a setting unit that sets the operation of the projector corresponding to whether the projection lens is the first projection lens or the second projection lens; The input receiving unit includes When the determination unit can not determine, characterized by receiving an input of said lens information.
According to this configuration, when it is not possible to determine whether the projection lens is the first projection lens or the second projection lens, input of lens information is accepted. Therefore, settings relating to the operation of the projector can be appropriately performed in accordance with the type of projection lens.

Further, according to the present invention, the setting unit performs setting based on a determination result when the determination unit can determine, and when the determination unit cannot determine, based on the lens information that the input reception unit has received an input. It is characterized by setting.
According to this configuration, when the discriminating unit is able to discriminate, the setting is performed based on the discrimination result, and when the discriminating unit cannot be discriminated, the setting is performed based on the lens information. Settings relating to the operation of the projector can be appropriately performed in correspondence with the lens.

In the present invention, when the projection lens is the first projection lens, the image information is processed using a first parameter, and when the projection lens is the second projection lens, the first lens is used. An image information processing unit that processes the image information using a second parameter different from the first parameter, and the setting unit uses the first parameter used by the image information processing unit or the second parameter. It is characterized by setting parameters.
According to this configuration, when the projection lens is the first projection lens, the parameter used by the image information processing unit is set to the first parameter, and when the projection lens is the second projection lens, the second Set the parameter. Therefore, image information can be processed with parameters corresponding to the type of projection lens.

The present invention further includes a lens driving unit that drives the projection lens according to a parameter, and the setting unit is configured such that the projection lens is the first projection lens or the projection lens is the second projection lens. The parameter relating to the operation of the lens driving unit is set according to whether or not.
According to this configuration, in order to set the parameter relating to the operation of the lens driving unit according to whether the projection lens is the first projection lens or the second projection lens, the first projection lens or the second projection lens is set. The projection lens can be driven in correspondence with the projection lens.

Further, the present invention is characterized in that the input receiving unit causes the projection unit to project a menu screen for inputting the lens information when the determination unit cannot determine.
According to this configuration, since the menu screen for inputting lens information is projected by the projection unit, even if the type of projection lens cannot be determined, the type of projection lens is set by the user's type input. it can.

Further, the present invention is characterized in that the input receiving unit does not receive an input to the menu screen when the determining unit determines.
According to this configuration, when the projection lens is determined, input to the menu screen is not accepted, so the user operates the menu screen even though the projection lens type is automatically acquired, and the wrong projection lens type is The occurrence of a situation such as setting can be prevented.

In order to achieve the above object, the present invention includes a light source unit that emits first light and a light modulation unit that emits second light obtained by modulating the first light according to image information. And a projection unit that projects the second light onto a projection surface through a projection lens, wherein the projection lens is the first projection lens or the first projection lens. Information indicating that the projection lens is the first projection lens, or information indicating that the projection lens is the second projection lens. Functions to accept input of lens information including, and functions to set the operation of the projector corresponding to whether the projection lens is the first projection lens or the second projection lens, The projection lens is the first If the can not determine whether a second projection lens or a projection lens, and wherein the receiving input of the lens information.
According to this configuration, when it is not possible to determine whether the projection lens is the first projection lens or the second projection lens, the projection lens is the first projection lens or the second projection lens. The input of information indicating is accepted. Therefore, settings relating to the operation of the projector can be appropriately performed in accordance with the type of projection lens.

The block diagram which shows the structure of a projector. The flowchart which shows operation | movement of a projector. The figure which shows an example of a menu screen.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration of the projector 100.

  The projector 100 projects image light onto a projection target, and forms an image based on image data (image information) on the projection target surface. The projection target on which the projector 100 projects an image may be a flat surface, a curved surface, or an uneven surface, but in the present embodiment, a case of projecting onto a screen SC (projection surface) configured with a flat surface is exemplified. . The screen SC may use a fixed plane such as a wall surface, or may be a curtain-type screen such as a lifting type or a rising type. The projector 100 is provided with a projection opening (not shown) for projecting image light. The projection opening is an opening through which the projection optical system 113 built in the projector 100 emits light.

  As shown in FIG. 1, the projector 100 includes an interface unit (hereinafter abbreviated as I / F unit) 124. As the I / F unit 124, for example, a DVI interface, a USB interface, a LAN interface, or the like to which a digital video signal is input can be used. In addition, the I / F unit 124 includes, for example, an S video terminal to which a composite video signal such as NTSC, PAL, or SECAM is input, an RCA terminal to which a composite video is input, or a D terminal to which a component video signal is input. Etc. can be used. Furthermore, a general-purpose interface such as an HDMI connector according to the HDMI (registered trademark) standard can be used for the I / F unit 124.

  The projector 100 includes a projection unit 110 that roughly forms an optical image, and an image processing system that electrically processes an image signal input to the projection unit 110.

  The projection unit 110 includes a light source unit 111, a light modulation device 112 (light modulation unit) including a liquid crystal panel 112A, and a projection optical system 113.

  The light source unit 111 includes a light source including a xenon lamp, an ultra-high pressure mercury lamp, an LED (Light Emitting Diode), a laser, and the like. The light source unit 111 emits the first light emitted from the light source to the light modulation device 112. The light source unit 111 may include a reflector for guiding the first light emitted from the light source to the light modulation device 112 and an auxiliary reflector. The light source unit 111 includes a lens group for enhancing the optical characteristics of the projection light, a polarizing plate, a light control element that reduces the amount of light emitted from the light source on the path to the light modulation device 112, etc. May also be provided).

The light modulation device 112 includes, for example, a transmissive liquid crystal panel 112A, and forms an image on the liquid crystal panel 112A in response to a signal from an image processing system described later. In this case, the light modulation device 112 includes three liquid crystal panels 112A corresponding to the three primary colors of RGB for color projection, and the first light from the light source unit 111 is separated into three colors of RGB color light. Each color light enters the corresponding liquid crystal panel 112A. The color light modulated by passing through each liquid crystal panel 112 </ b> A is combined by a combining optical system such as a cross dichroic prism and emitted to the projection optical system 113. That is, the light modulation device 112 modulates the first light emitted from the light source, and emits the second light obtained by modulating the first light to the projection optical system 113.
The light modulation device 112 is not limited to the configuration using three transmissive liquid crystal panels 112A, and for example, three reflective liquid crystal panels may be used. Further, the light modulation device 112 may be configured by a method in which one liquid crystal panel and a color wheel are combined. Here, when only one liquid crystal panel 112A or DMD (Digital Mirror Device) is used as the light modulation device 112, a member corresponding to a combining optical system such as a cross dichroic prism is unnecessary. In addition to the liquid crystal panel 112A and the DMD, any configuration capable of modulating the first light emitted from the light source unit 111 can be employed.

  The projection optical system 113 includes a projection lens 113A, and radiates incident light (second light) modulated by the light modulation device 112 outward from a projection opening (not shown) through the projection lens 113A. A projected image is formed on the SC. The projection optical system 113 is configured such that the projection lens 113A can be replaced. The projection lens 113A is a normal projection lens (first projection lens) that is a normal projection lens, or a projection lens (second projection lens) that is different from the normal projection lens. The normal projection lens is a projection lens that is attached to the projector 100 when the projector 100 is shipped from the factory. The projection lens different from the normal projection lens is, for example, a projection lens having a field angle value different from that of the normal projection lens, and includes a wide-angle lens (second projection lens), a telephoto lens (second projection lens), and the like. . Examples of the projection lens different from the normal projection lens include an anamorphic lens that changes the aspect ratio of the projected image, and a short focus lens.

  A projection optical system driving unit 121 (lens driving unit) and a light source driving unit 122 are connected to the projection unit 110. The projection optical system drive unit 121 drives each motor included in the projection optical system 113 under the control of the control unit 130 described later, and drives the projection lens 113A. Further, the projection optical system drive unit 121 controls the detection unit 127.

  The detection unit 127 detects the type of the projection lens 113A included in the projection optical system 113. For example, when the projection lens 113A includes an IC that stores type information indicating the type of the projection lens 113A, the detection unit 127 acquires the type information from the IC included in the projection lens 113A and detects the type of the projection lens 113A. . The type information acquired by the detection unit 127 includes a model number of the projection lens 113A, a code indicating the type of the projection lens 113A, and the like. The detection result is output to the control unit 130. In addition, the detection method of the detection part 127 is an example, and is not limited to the method mentioned above.

  The light source driving unit 122 drives the light source included in the light source unit 111 according to the control of the control unit 130.

  The projection optical system driving unit 121 and the light source driving unit 122 are connected to the bus 105.

  The projector 100 includes a communication unit 156. The communication unit 156 is connected to the bus 105. The communication unit 156 communicates with an external device according to a communication standard according to the control of the control unit 130.

  The image processing system included in the projector 100 is configured around a control unit 130 that controls the entire projector 100 in an integrated manner. In addition, a storage unit 151, an image processing unit 125 (image information processing unit), and a light modulation device driving unit 123. The input processing unit 153 is provided. The control unit 130, the storage unit 151, the input processing unit 153, the image processing unit 125, and the light modulation device driving unit 123 are each connected to the bus 105.

  The control unit 130 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like (not shown), and controls the projector 100 by executing a control program stored in the ROM by the CPU. In addition, the control unit 130 reads out and executes the control program stored in the storage unit 151, whereby a projection control unit 131, a communication control unit 132, a lens type acquisition unit 133, a determination unit 134, and an input reception unit 135 described later. And function as the setting unit 136.

  The storage unit 151 includes a nonvolatile memory such as a flash memory or an EEPROM (Electrically Erasable Programmable Read-Only Memory), and stores various data in a rewritable manner. The storage unit 151 stores a control program used for controlling the projector 100, image data, and the like.

  In addition, the storage unit 151 stores the type information 151 a indicating the type of the projection lens 113 </ b> A and the parameter 151 b used when setting the operation of the projector 100 in association with each other. The parameter 151b includes an image parameter used when the image processing unit 125 processes image data and a lens parameter used when driving the projection lens 113A.

  Specifically, the storage unit 151 stores the type information 151a indicating the normal projection lens and the parameter 151b for setting the operation of the projector 100 in the normal projection lens in association with each other. The parameter 151b for setting the operation of the projector 100 in the normal projection lens includes an image parameter (first parameter) used by the image processing unit 125 when the normal projection lens is attached, and the projection optical system driving unit 121. Including lens parameters to be used.

  In addition, the storage unit 151 stores the type information 151a indicating the projection lens 113A different from the normal projection lens and the parameter 151b for setting the operation of the projector 100 in the projection lens 113A in association with each other. The number of types information stored in the storage unit 151 may be the number of all types of projection lenses that can be used in the projector 100, or may be the number of types of projection lenses set in advance by the user. Parameters for setting the operation of the projector 100 in the projection lens 113A different from the normal projection lens include an image parameter (second parameter) used by the image processing unit 125 when the projection lens 113A is attached, and the projection. Lens parameters used by the projection optical system drive unit 121 in the lens 113A. For example, the storage unit 151 associates and stores type information 151a indicating a wide-angle lens and a parameter 151b for setting the operation of the projector 100 in the wide-angle lens. The parameter 151b includes an image parameter (second parameter) used by the image processing unit 125 and a lens parameter used by the projection optical system driving unit 121 when a wide-angle lens is attached. Further, for example, the storage unit 151 stores the type information 151a indicating the telephoto lens and the parameter 151b for setting the operation of the projector 100 in the telephoto lens in association with each other. The parameter 151b includes an image parameter used by the image processing unit 125 and a lens parameter used by the projection optical system driving unit 121 when a telephoto lens is attached.

  The image processing unit 125 executes resolution conversion processing that converts the image data input from the I / F unit 124 into data having a resolution that conforms to the specifications of the liquid crystal panel 112A of the light modulation device 112. The image processing unit 125 draws a display image to be displayed by the light modulation device 112 in the frame memory 126 and outputs the drawn display image to the light modulation device driving unit 123. The light modulation device driving unit 123 drives the light modulation device 112 based on the display image input from the image processing unit 125. As a result, an image is drawn on the liquid crystal panel 112A of the light modulation device 112, and the drawn image is projected as a projection image on the screen SC via the projection optical system 113.

The projector 100 includes various switches for the user to perform operations and an operation panel 155 including an indicator lamp. The operation panel 155 is connected to the input processing unit 153. The input processing unit 153 appropriately turns on or blinks the indicator lamp of the operation panel 155 according to the operation state or setting state of the projector 100 according to the control of the control unit 130. When a switch on the operation panel 155 is operated, an operation signal corresponding to the operated switch is output from the input processing unit 153 to the control unit 130.
Further, the projector 100 has a remote control (not shown) used by the user. The remote control includes various buttons, and transmits an infrared signal corresponding to the operation of these buttons. The projector 100 includes a remote control light receiving unit 154 that receives an infrared signal emitted from the remote control. The remote control light receiving unit 154 decodes the infrared signal received from the remote control, generates an operation signal indicating the operation content on the remote control, and outputs the operation signal to the control unit 130.

  Next, the projection control unit 131, the communication control unit 132, the lens type acquisition unit 133, the determination unit 134, the input reception unit 135, and the setting unit 136 included in the control unit 130 will be described.

  The projection control unit 131 controls the image processing unit 125 to cause the frame memory 126 to draw an image based on the image data supplied via the I / F unit 124. Further, the projection control unit 131 controls the image processing unit 125 to cause the frame memory 126 to draw an image based on the image data stored in the storage unit 151. The projection control unit 131 controls the light modulation device driving unit 123 to draw the image drawn in the frame memory 126 on the liquid crystal panel 112A of the light modulation device 112. The image drawn on the liquid crystal panel 112 </ b> A of the light modulation device 112 is projected as a projection image on the screen SC via the projection optical system 113.

  The communication control unit 132 controls the communication unit 156 to communicate with an external device.

  The lens type acquisition unit 133 controls the projection optical system drive unit 121 to acquire the type of the projection lens 113 </ b> A included in the projection optical system 113 by the detection unit 127. When the lens type acquisition unit 133 acquires the type information indicating the type of the projection lens 113 </ b> A from the detection unit 127, the lens type acquisition unit 133 outputs the acquired type information to the determination unit 134.

  Based on the type information indicating the type of the projection lens 113A input from the lens type acquisition unit 133, the determination unit 134 determines whether the projection lens 113A included in the projection optical system 113 is a normal projection lens or is different from the normal projection lens. It is determined whether it is a projection lens.

  The input receiving unit 135 controls the input processing unit 153 to use information indicating that the projection lens 113A is a normal projection lens or a projection lens different from the normal projection lens based on an operation of a remote controller, an operation panel, or the like. An input of lens information including information indicating the presence is received. When receiving input of lens information, the projection control unit 131 causes the projection unit 110 to project a menu screen (described later) for receiving lens information. And the input reception part 135 receives the input of the lens information with respect to a menu screen.

  The setting unit 136 sets image parameters used when the image processing unit 125 processes image data based on the parameters 151b stored in the storage unit 151. The setting unit 136 sets lens parameters used when the projection optical system driving unit 121 drives the projection lens 113A based on the parameters 151b stored in the storage unit 151.

  As described above, the projection optical system 113 is configured such that the projection lens 113A can be replaced. The projector 100 sets image parameters to be used when processing image data, and sets lens parameters for driving the projection lens 113A, in accordance with the type of the projection lens 113A attached. When acquiring the type of the mounted projection lens 113A, the projector 100 acquires the type of the projection lens 113A automatically or by user input. However, when the type of the projection lens 113A cannot be automatically acquired, or when the user manually inputs the type even though the type of the projection lens 113A can be automatically acquired, the appropriate type of the projection lens 113A is determined. Cannot be set. For this reason, the projector 100 may not be able to set parameters corresponding to the type of the projection lens 113A that is mounted.

  Therefore, the projector 100 according to the present embodiment executes the following operation.

  FIG. 2 is a flowchart showing the operation of the projector 100.

  The projection control unit 131 of the projector 100 determines whether or not the user has instructed to turn on the light source included in the light source unit 111 by operating the operation panel 155 or a remote controller (step S1). When it is determined that the light source is instructed to be turned on (step S1: YES), the projection control unit 131 controls the light source driving unit 122 to turn on the light source (step S2).

  Next, the lens type acquisition unit 133 starts acquiring the type of the projection lens 113A (step S3). That is, the lens type acquisition unit 133 controls the projection optical system drive unit 121 to acquire the type of the projection lens 113A included in the projection optical system 113 by the detection unit 127. When the projection lens 113A includes an IC that stores type information indicating the type of the projection lens 113A, the detection unit 127 acquires the type information of the projection lens 113A from the IC, and the acquired type information is the lens type acquisition unit 133. Output to.

  Next, the determination unit 134 determines whether the lens type acquisition unit 133 can determine the type of the projection lens 113A based on the information input from the detection unit 127 (step S4). When the information acquired from the detection unit 127 by the lens type acquisition unit 133 is the type information of the projection lens 113A, the determination unit 134 determines that the type of the projection lens 113A can be determined. On the other hand, the determination unit 134 determines the type of the projection lens 113A when information indicating that the information acquired by the lens type acquisition unit 133 from the detection unit 127 cannot detect the type information of the projection lens 113A is input. It is determined that it is impossible. The determination unit 134 counts a predetermined period after the lens type acquisition unit 133 starts acquiring the type information of the projection lens 113A by a timer or the like (not shown), and within the predetermined period, the lens type acquisition unit When 133 does not acquire type information from the detection unit 127, it may be determined that the type of the projection lens 113A cannot be determined.

  Next, when the determination unit 134 determines that the type of the projection lens 113A cannot be determined (step S4: NO), the projection control unit 131 projects a menu screen (step S5). The case where the determination unit 134 determines that the type of the projection lens 113A can be determined will be described later.

  FIG. 3 is a diagram illustrating an example of the menu screen MG.

  The menu screen MG shown in FIG. 3 displays type information 151a of seven projection lenses 113A of type A to type G. The menu screen MG displays seven types of information 151a of type A to type G so as to be selectable by operating the remote control, the operation panel 155, or the like. As a result, the user can select the type information 151a displayed on the menu screen MG with the remote control or the operation panel 155, and the projection lens 113A attached to the projector 100 is of the type indicated by the selected type information 151a. Lens information indicating that the lens is a projection lens can be input.

  When the projection control unit 131 projects the menu screen MG, the input receiving unit 135 of the projector 100 receives an operation for selecting the type information 151a by the user. When a selection operation is performed on the type information 151a, the input receiving unit 135 receives an input of lens information indicating that the projection lens 113A is the type of projection lens indicated by the selected type information 151a. For example, when “type A” is selected by the user among the plurality of types of information 151a shown in FIG. 3, the input receiving unit 135 indicates that the mounted projection lens 113A is a projection lens of the type “type A”. Lens information indicating that there is present is received.

  Returning to the description of the flowchart, the input receiving unit 135 determines whether lens information has been received (step S6). When the input receiving unit 135 determines that the lens information has been received (step S6: YES), the setting unit 136 corresponds to the type of the projection lens 113A indicated by the lens information based on the lens information received by the input receiving unit 135. The parameter 151b is set (step S7).

  For example, when the user selects “type A” on the menu screen MG illustrated in FIG. 3, the input reception unit 135 receives lens information indicating that the projection lens 113 </ b> A is a type of “type A” projection lens. . Next, the setting unit 136 refers to the type information 151a stored in the storage unit 151, and sets a parameter 151b corresponding to the type information 151a indicating “type A”.

  Returning to the description of step S6, when the input reception unit 135 determines that lens information is not received (step S6: NO), the process proceeds to step S8. The input reception unit 135 determines that lens information is not received when the user selects the button B indicating “return” included in the menu screen MG without selecting the type information 151a to be displayed. The input receiving unit 135 counts a predetermined period after the projection control unit 131 projects the menu screen MG by a timer or the like (not shown), and the user can select the type information 151a to be displayed within the predetermined period. A configuration may be adopted in which lens information is not received when there is no operation.

  Next, when the input receiving unit 135 determines that the lens information is not received, the setting unit 136 sets the parameter 151b set last time (step S8). The parameter 151b set last time is the parameter 151b corresponding to the type of the projection lens 113A acquired last time.

  Returning to the description of step S4, when the determination unit 134 determines that the type of the projection lens 113A can be determined (step S4: YES), the determination unit 134 uses the type information of the projection lens 113A acquired by the lens type acquisition unit 133. Based on this, the type of the mounted projection lens 113A is determined (step S9). For example, when the type information indicating the type of the normal projection lens is input from the lens type acquisition unit 133 for the projection lens 113A attached to the projector 100, the determination unit 134 normally uses the projection lens 113A attached to the projector 100. It is determined that it is a projection lens.

  Next, the setting unit 136 sets a parameter 151b corresponding to the type of the projection lens 113A based on the determination result of the determination unit 134 (step S10). For example, when the determination unit 134 determines in step S9 that the projection lens 113A attached to the projector 100 is a normal projection lens, the setting unit 136 refers to the type information 151a stored in the storage unit 151, and the normal projection lens Is set to the parameter 151b corresponding to the type information 151a.

  Moreover, the input reception part 135 does not receive the input of the lens information with respect to the menu screen MG (step S10). That is, even when the menu screen MG is projected by the user's operation, if the determination unit 134 can determine, the input reception unit 135 puts the menu screen MG into a state where it does not receive input of lens information. Specifically, the input receiving unit 135 does not receive an operation for selecting the type information 151a on the menu screen MG. In this case, the projection control unit 131 projects the menu screen MG in a manner different from the menu screen MG that is projected when the determination unit 134 cannot determine the type of the projection lens 113A, such as graying out the menu screen MG.

  Accordingly, since the lens information input to the menu screen MG is not accepted, the user operates the menu screen MG even though the type of the projection lens 113A can be automatically acquired, and the wrong type of the projection lens 113A is set. Such a situation can be prevented. In addition, since the menu screen MG is grayed out, it is possible to notify the user that the type information 151a cannot be selected, and the probability that the user cannot recognize that the type of the projection lens 113A cannot be set increases.

  Next, when setting the parameter 151b corresponding to the type of the projection lens 113A, the control unit 130 of the projector 100 determines whether or not the operation of the projector 100 has been instructed (step S11). When it is determined that the operation of the projector 100 is instructed by the operation of the user's remote control or the operation panel 155 (step S11: YES), the control unit 130 executes the instructed operation using the set parameter 151b (step S11: YES). Step S12).

For example, when a normal projection lens is attached to the projector 100, the setting unit 136 sets a parameter 151b corresponding to the normal projection lens. In this case, when an instruction to execute trapezoidal correction for correcting the trapezoidal projection image into an appropriate shape is issued by the user's operation, the projector 100 uses the image processing unit 125 to process the image data. Perform keystone correction based on the parameters. Specifically, the image parameter includes a keystone correction parameter related to the keystone correction, and the image processing unit 125 performs the keystone correction on the image data using the keystone correction parameter.
The trapezoidal correction is exemplified as the correction in which the image processing unit 125 processes the image data and corrects the projection image to an appropriate shape. . In this case, the parameter 151b corresponding to the projection lens 113A attached to the projector 100 includes a curvature correction parameter related to the curvature correction, and the image processing unit 125 performs the curvature correction on the image data using the curvature correction parameter. To do.

For example, when a wide-angle lens is attached to the projector 100, the setting unit 136 sets a parameter 151b corresponding to the wide-angle lens. In this case, when there is an instruction to execute a lens shift for moving the projection position of the projection image, the projector 100 is based on the lens parameters used when the projection optical system driving unit 121 drives the projection lens 113A. Perform lens shift. Specifically, the lens parameter includes a lens shift parameter related to the lens shift, and the projection optical system driving unit 121 uses the lens shift parameter to move the position of the wide-angle lens to execute the lens shift.
The lens shift is exemplified as the adjustment in which the projection optical system drive unit 121 drives the projection lens 113A to adjust the projection image. In this case, the parameter 151b corresponding to the projection lens 113A attached to the projector 100 includes parameters related to zoom, focus, etc., and the projection optical system drive unit 121 uses the parameters related to zoom, focus, etc. 113A is driven to execute zoom, focus, and the like.

  As described above, the projector 100 according to this embodiment emits the first light and the second light obtained by modulating the first light according to the image data (image information). It has the light modulation apparatus 112 (light modulation part) to radiate | emit, and has the projection part 110 which projects 2nd light on the screen SC (projection surface) through the projection lens 113A. In the projector 100, whether the projection lens 113A is a normal projection lens (first projection lens) or a projection lens different from the normal projection lens (second projection lens different from the first projection lens). A discriminating unit 134 for discriminating the above. Further, the projector 100 receives an input of lens information including information indicating that the projection lens 113A is a normal projection lens or information indicating that the projection lens 113A is a projection lens different from the normal projection lens. 135. In addition, the projector 100 includes a setting unit 136 that sets the operation of the projector 100 corresponding to the projection lens 113A. The input receiving unit 135 receives an input of lens information when the determining unit 134 cannot determine.

  Thereby, when the determination unit 134 cannot determine the type of the projection lens 113A, the input of lens information is accepted. For this reason, it is possible to appropriately perform settings related to the operation of the projector 100 in accordance with the type of the projection lens 113A.

  The setting unit 136 performs setting based on the determination result when the determination unit 134 can determine the type of the projection lens 113A. When the determination unit 134 cannot determine the type of the projection lens 113A, the input reception unit 135 Set based on lens information received.

  As described above, the setting unit 136 performs setting based on the determination result when the determining unit 134 can determine, and performs setting based on the lens information when the determining unit 134 cannot determine the type of the projection lens 113A. Therefore, the setting unit 136 can appropriately perform settings related to the operation of the projector 100 corresponding to the projection lens 113A regardless of whether the determination unit 134 can determine.

  In addition, the projector 100 includes an image processing unit 125 (image information processing unit). The image processing unit 125 processes the image data using the image parameters included in the parameter 151b corresponding to the projection lens 113A. The setting unit 136 sets image parameters used by the image processing unit 125.

  In this manner, the setting unit 136 sets image parameters that the image processing unit 125 uses image data for processing, corresponding to the projection lens 113A. Therefore, the image processing unit 125 can appropriately process the image data with the image parameter corresponding to the projection lens 113A. For example, since the image processing unit 125 uses image parameters corresponding to the projection lens 113A, the image processing unit 125 can execute correction of the shape of the projection image such as trapezoidal correction and curvature correction corresponding to the projection lens 113A.

  The projector 100 also includes a projection optical system drive unit 121 (lens drive unit) that drives the projection lens 113A according to the parameter 151b. The setting unit 136 sets parameters related to the operation of the projection optical system driving unit 121 corresponding to the type of the projection lens 113A.

  Thereby, since the parameter concerning the operation of the projection optical system driving unit 121 is set corresponding to the type of the projection lens 113A, the projection lens 113A can be driven corresponding to the type of the projection lens 113A. For example, the projection optical system drive can drive the projection lens 113A corresponding to the type of the projection lens 113A in lens shift, zoom, focus, or the like.

  The input receiving unit 135 causes the projection unit 110 to project a menu screen MG for inputting lens information when the determination unit 134 cannot determine the type of the projection lens 113A.

  Accordingly, since the menu screen MG is projected by the projection unit 110, even if the determination unit 134 cannot determine the type of the projection lens 113A, the type of the projection lens 113A can be set by an input by the user.

  Further, the input receiving unit 135 does not receive an input to the menu screen MG when the determining unit 134 determines the type of the projection lens 113A.

  As a result, when the type of the projection lens 113A is determined, input to the menu screen MG is not accepted, so that the user operates the menu screen MG even though the type of the projection lens 113A is automatically acquired, and an incorrect projection lens is obtained. It is possible to prevent a situation in which the type of 113A is set.

  The above-described embodiments and modifications are examples of the preferred embodiments of the present invention, and various modifications can be made without departing from the scope of the present invention.

  For example, in the above-described embodiment, when the determination unit 134 of the projector 100 determines the type of the projection lens 113A, the input reception unit 135 exemplifies a configuration that does not receive an input operation on the menu screen MG. However, the present invention is not limited to this configuration, and may be a configuration that does not accept an operation for transitioning to the menu screen MG.

  Further, for example, the projector 100 described above may be a front projection type projector that projects from the front of the screen SC, or a rear projection (rear projection) type projector that projects from the back side of the screen SC.

  Further, for example, the processing unit of FIG. 2 is divided according to main processing contents in order to make the processing of the projector 100 easy to understand, and the present invention is limited by the method and name of dividing the processing unit. It will never be done. The processing of the projector 100 may be divided into a number of processing units depending on the processing content. Moreover, you may divide | segment so that one process unit may contain many processes.

  Moreover, each function part shown in FIG. 1 shows a functional structure, and the specific mounting form is not specifically limited. That is, it is not always necessary to mount hardware corresponding to each function unit individually, and it is of course possible to adopt a configuration in which the functions of a plurality of function units are realized by one processor executing a program. In each of the above-described embodiments, a part of functions realized by software may be hardware, or a part of functions realized by hardware may be realized by hardware. In addition, the specific detailed configuration of each other part of the projector 100 can be arbitrarily changed without departing from the gist of the present invention.

  DESCRIPTION OF SYMBOLS 100 ... Projector, 105 ... Bus, 110 ... Projection part, 111 ... Light source part, 112 ... Light modulation apparatus (light modulation part), 112A ... Liquid crystal panel, 113 ... Projection optical system, 113A ... Projection lens, 121 ... Projection optical system Drive unit 122... Light source drive unit 123. Light modulator drive unit 124 124 I / F unit 125 Image processor (image information processing unit) 126 Frame memory 127 Detection unit 130 Control unit 131 ... Projection control unit, 132 ... Communication control unit, 133 ... Lens type acquisition unit, 134 ... Discrimination unit, 135 ... Input reception unit, 136 ... Setting unit, 137 ... Input reception unit, 151 ... Storage unit, 151a ... Type Information, 151b ... parameter, 153 ... input processing unit, 154 ... remote control light receiving unit, 155 ... operation panel, 156 ... communication unit, SC ... screen.

Claims (7)

A projector,
A light source unit that emits the first light; and a light modulation unit that emits the second light obtained by modulating the first light in accordance with image information, and the second light is transmitted through the projection lens. A projection unit that projects the projection surface;
A determination unit for determining whether the projection lens is a first projection lens or a second projection lens different from the first projection lens;
An input receiving unit for receiving input of lens information including information indicating that the projection lens is the first projection lens or information indicating that the projection lens is the second projection lens;
A setting unit configured to set the operation of the projector corresponding to whether the projection lens is the first projection lens or the second projection lens;
The input receiving unit
When the discrimination unit cannot discriminate, accept the input of the lens information.
A projector characterized by that. The setting unit
If the discriminator can discriminate, set based on the discrimination result,
If the determination unit can not be determined, the input reception unit is set based on the lens information received input,
The projector according to claim 1. When the projection lens is the first projection lens, the image information is processed using a first parameter, and when the projection lens is the second projection lens, the first parameter is different from the first parameter. An image information processing unit that processes the image information using two parameters;
The setting unit sets the first parameter or the second parameter used by the image information processing unit;
The projector according to claim 1, wherein: According to the parameters, provided with a lens driving unit for driving the projection lens,
The setting unit
Corresponding to whether the projection lens is the first projection lens or the projection lens is the second projection lens, a parameter related to the operation of the lens driving unit is set.
The projector according to claim 1, wherein: The input receiving unit
When the determination unit cannot be determined, the projection unit projects a menu screen for inputting the lens information.
The projector according to claim 1, wherein the projector is a projector. The input receiving unit
If the determination unit determines, does not accept input to the menu screen,
The projector according to claim 5. A light source unit that emits the first light; and a light modulation unit that emits the second light obtained by modulating the first light in accordance with image information, and the second light is transmitted through the projection lens. A projection unit that projects onto a projection surface, and a projector control method comprising:
Function to determine whether the projection lens is a first projection lens or a second projection lens different from the first projection lens;
Functions to accept input of lens information including information indicating that the projection lens is the first projection lens or information indicating that the projection lens is the second projection lens;
Corresponding to whether the projection lens is the first projection lens or the second projection lens, it functions to set the operation of the projector,
When it is not possible to determine whether the projection lens is the first projection lens or the second projection lens, an input of the lens information is received.
A projector control method characterized by that.

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