JP2012242487A - Projector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a projector which makes a display image easily seen.SOLUTION: A projector (1) is capable of projecting images in a first projection mode which enables a display of a first image of first image data acquired via an external interface (19A) or a second projection mode which enables a display of a second image of second image data stored in storage means (19B, 20). The projector (1) has a control part (10) for outputting control signals, which, in the first projection mode, rotate the first image to be displayed in an image display part (22) at 180 degrees, and in the second projection mode, can instruct an image processing part (16) to switch between a portrait display mode and a landscape display mode for the second image and rotate the second image to be displayed in the image display part (22) at 180 degrees.

Description

  The present invention relates to a projector.

  Conventionally, there is a projection apparatus that projects an image from an oblique direction on a desk on which the projection apparatus is installed (see the following patent publication). According to this projection apparatus, it is possible to display an optimal projection image for the observer at a free position on the desk.

JP 2003-280091 A

  However, when an image captured in a vertical position (position obtained by rotating a horizontal camera by 90 ° around the optical axis of the lens) with a digital camera or the like is displayed on a screen by a projector, the vertical image is projected on a horizontal display area. As a result, the image displayed in the display area is reduced and is difficult to see.

  The present invention has been made in view of such circumstances, and an object thereof is to provide a projector capable of making a display image easy to see.

  In order to solve the above-mentioned problem, the invention according to claim 1 is the first projection mode capable of displaying the first image of the first image data acquired via the external interface, or the second image stored in the storage means. In a projector capable of projecting a second projection mode capable of displaying a second image of data, in the first projection mode, the first image displayed on the image display unit is rotated by 180 degrees, and the second projection mode is displayed. In the projection mode, the image processing unit can be instructed to switch between the vertical and horizontal display of the second image, and includes a control unit that outputs a control signal for rotating the second image displayed on the image display unit by 180 degrees. It is characterized by.

  According to a second aspect of the present invention, in the projector according to the first aspect, the control unit rotates the first and second images using a function of an image display driver.

    According to a third aspect of the invention, in the projector according to the first or second aspect, the control unit adds the vertical position added to the second image data before instructing the switching of the vertical and horizontal display of the second image. The display direction of the second image is determined based on the information.

    According to a fourth aspect of the present invention, in the projector according to the first or second aspect, when the second image data is moving image data to which the vertical position information is not added, the control unit controls the image processing unit. The switching of the vertical and horizontal display of the second image is not instructed.

  According to a fifth aspect of the present invention, in the projector according to any one of the first to fourth aspects, an operation member is provided that instructs the control unit to rotate the first and second images. To do.

  According to a sixth aspect of the present invention, in the projector according to any one of the first to fifth aspects, the control unit stores the top / bottom / left / right information and the vertical position information of the control signal as values of a status flag, The value of the state flag transmitted to the image display unit is rewritten based on the value of the state flag stored when the operation member is operated.

  According to the present invention, it is possible to make a display image easy to see.

FIG. 1 is a block diagram showing a projection apparatus according to an embodiment of the present invention. FIG. 2 is a conceptual diagram showing a projection unit. FIG. 3 is a diagram showing the relationship between the orientation of the image display element and its display. FIG. 4 is a diagram for explaining vertical display and horizontal display of a display image. FIG. 5 is a plan view showing an operation member of the projector according to the embodiment of the present invention. FIG. 6 is a diagram for explaining the image display direction of the image display element of the projector. FIG. 7A is a diagram for explaining the rotation of the display image of the projector according to the comparative example. FIG. 7B is a diagram illustrating the relationship between the number of times the rotation instruction button of the projector in FIG. 7A is pressed and the display image. FIG. 8 is a flowchart for explaining the operation of the projector according to the comparative example. FIG. 9A is a diagram illustrating rotation of a display image of the projector according to an embodiment of the present invention. FIG. 9B is a diagram for explaining the relationship between the number of times the rotation instruction button is pressed and the display image. FIG. 10 is a diagram for explaining the image display direction of the image display element of the projector. FIG. 11 is a flowchart for explaining the operation of the projector according to the embodiment of the invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a block diagram of a projector 1 according to an embodiment of the present invention, and FIG. 2 is a conceptual diagram showing a projection unit 2 of the projector 1. In FIG. 2, the LED light sources 21a to 21c are illustrated in a simplified manner.

  The projector 1 includes a CPU (control unit) 10 that is a main control unit. The CPU 10 includes LED light sources 21 a to 21 c, an illumination unit 21 that illuminates an image display element 22 described later, a battery 18 that drives the illumination unit 21, and a main switch (ON / OFF) that turns on and off the power supply unit 14. ) Operation member such as 12, projection light source drive circuit 15 that turns on and off the LED light sources 21a to 21c, projection light source drive circuit 15, and image display driver 17 that drives the image display element (image display unit) 22, and images A processing unit 16 and a signal conversion unit 19 are connected.

  When the main switch 12 is pressed, the CPU 10 outputs a power supply activation signal 10a to activate the power supply unit 14.

  An external interface 19A (external I / F) is connected to the signal conversion unit 19. The external interface 19A transmits and receives image data, projector control data, and the like to and from an external device (not shown). When the control signal 10e from the CPU 10 is input, the signal converter 19 A / D converts an analog video signal such as image data input from the external interface 19A, and outputs a digital image signal 19c to the image display driver 17. To do. In addition, the signal conversion unit 19 performs scaling such as image enlargement / reduction and aspect ratio change to match the display resolution of the image display element 22.

  The image processing unit 16 is connected to a memory card 19B and a built-in memory 20 (memory). Image data 19b and 20b are stored in advance in the memory card 19B and the built-in memory 20. The memory card 19B is a storage medium such as a CF card (registered trademark) or an SD card (registered trademark). The memory card 19B and the built-in memory 20 constitute storage means of claim 1.

  For example, the image processing unit 16 reads image data from the built-in memory 20 and performs scaling such as image enlargement / reduction and aspect ratio change to match the display resolution of the image display element 22 in the same manner as the external interface 19A.

  Further, when the control signal 10 e from the CPU 10 is input, the image processing unit 16 outputs an image signal 16 b such as image data from the built-in memory 20 to the image display driver 17. The image processing unit 16 has a function of rotating the display image by 90 ° based on the image data from the built-in memory 20 (switching the vertical / horizontal display of the display image).

  When the control signal 10e from the CPU 10 is input, the image display driver 17 outputs an image signal 17c for driving the image display element 22 in accordance with the image signal 19c output from the signal conversion unit 19.

  Further, when the control signal 10e from the CPU 10 is input, the image display driver 17 outputs an image signal 17c for driving the image display element 22 in accordance with the image signal 16b output from the image processing unit 16. .

  The image display element 22 is, for example, a reflective LCOS (Liquid Crystal On Silicon). LCOS is a reflective liquid crystal display panel in which a liquid crystal layer is formed on a silicon substrate.

  The image display element 22 has a function of rotating the display image by 180 degrees based on image data from the external interface 19A or image data from the built-in memory 20.

  The LED light sources 21a to 21c, which are projection light sources, are composed of LEDs of three colors, red (R) 21a, green (G) 21b, and blue (B) 21c. The LED is a high-intensity LED that emits high-intensity light. When the LED lighting signal 10b is input from the CPU 10 to the projection light source driving circuit 15, the LED light sources 21a to 21c are in a state where they can be lit. Based on the lighting timing signal 17b of the image display driver 17, the power supply to the red (R) 21a, green (G) 21b, and blue (B) 21c is controlled, and the red (R) 21a, green (G) 21b, blue (B) 21c is turned on and off. The lighting timing signal 17b from the image display driver 17 to the projection light source drive circuit 15 and the image signal 17c to the image display element 22 are synchronized, and when the image display element 22 displays the density of the red color component. Similarly, the red LED 21a is turned on. Similarly, the green LED 21b is turned on when the green color component is shaded, and the blue LED 21c is turned on when the shade is the blue color component. The LED light sources 21a to 21c are turned on / off and the image display element 22 is switched at high speed, and is recognized as a full-color optical image on the installation surface G or the like.

  The LED light sources 21a to 21c can be reduced in size including the power source as compared with the discharge-type light source lamp, and can be instantly turned on and off, and can be used as a light source even if the brightness change is repeated in a short time. It has many advantages as a light source for a projector, such as being capable of stable light emission with a small load and a long lifetime.

  The image display driver 17, the projection light source drive circuit 15, the image display element 22, the LED light sources 21a to 21c, the PBS (polarization beam splitter) block 23, and the projection lens 24 constitute the projection unit 2 (see FIG. 2). The PBS block 23 is obtained by sandwiching a polarization separation surface forming an angle of 45 degrees with respect to the incident axes of the LED light sources 21a to 21c between two triangular prisms.

  The projection unit 2 will be described based on FIG.

  When drive current is supplied from the projection light source drive circuit 15 to the LED light sources 21 a to 21 c, the light from the LED light sources 21 a to 21 c enters the PBS block 23. The light beam incident on the PBS block 23 is separated into S-polarized light and P-polarized light on the polarization separation surface of the PBS block 23. Therefore, only the S-polarized light is reflected by the polarization separation surface, and the P-polarized light is transmitted through the polarization separation surface, whereby only the S-polarized light illuminates the image display element 22.

  The light beam that has entered the image display element 22 travels through the liquid crystal layer, is reflected by a reflecting surface (not shown), and then enters the PBS block 23 again. Since the S-polarized light has changed to P-polarized light in the process of reciprocating the liquid crystal layer, the light beam incident on the PBS block 23 passes through the polarization separation surface and travels toward the projection lens 24 as projection light. The light beam incident on the projection lens 24 is transmitted through the projection lens 24 and a full-color optical image is enlarged and displayed on the installation surface G or the like.

  FIG. 3 is a diagram showing the relationship between the orientation of the image display element 22 and its display. The image display element 22 may be incorporated into the projector casing 50 (see FIG. 5) in a state where the top and bottom and the left and right are inverted due to restrictions on incorporation. In this case, for the purpose of adjusting the orientation of the display image, the control signals UD and LR are set to 0 or 1 as shown in FIGS. 3A, 3B, 3C, and 3D, respectively. The display direction of the image display element 22 can be freely changed.

3 (b) is an inversion of FIG. 3 (a) with respect to the virtual axis X, and FIG. 3 (d) is an inversion of FIG. 3 (b) with respect to the virtual axis Y. (C) is obtained by inverting FIG. 3 (d) with respect to the virtual axis X, and FIG. 3 (a) is obtained by inverting FIG. 3 (c) with respect to the virtual axis Y.
It is also possible to drive the image display driver 17 instead of the image display element 22 to send an image signal whose orientation in the vertical and horizontal directions has been changed in advance to the image display element 22.

  Therefore, regardless of how the image display element 22 is incorporated in the projector housing 50, the display shown in FIG. 3A can be obtained by setting the control signals to UD = 0 and LR = 0, for example.

  By the way, some digital cameras have a function of adding vertical position information (VH = 1) that the image was taken in the vertical position at the time of shooting to the image data.

  FIG. 4 is a diagram for explaining vertical display and horizontal display of a display image.

  In an image reproducing device that can identify vertical position information, when the vertical position information is detected by the image reproducing device, an image is displayed in a vertically long shape without any special operation (see FIG. 4A). At this time, margins are generated on both sides of the image (display image) displayed in the horizontally long display area PA.

  When image data to which vertical position information is not added is reproduced or when an image is reproduced on a device that cannot identify vertical position information, the display image is horizontally long (see FIG. 4B). At this time, an image is displayed in the entire display area PA.

  FIG. 5 is a plan view showing an operation member of the projector 1 according to the embodiment of the present invention, and FIG. 6 is a view for explaining the display direction of the image on the image display element 22 of the projector 1.

  In addition to the main switch (ON / OFF) 12 for turning on / off the power supply unit 14 as an operation member on the upper surface of the projector 1, a menu button 30 for moving to the menu mode, a cursor such as a menu button, and so on Move buttons 31a to 31d for moving to the position, a determination button (OK) 32 for enabling the setting of the position designated by the cursor, and a rotation instruction button (Rot.) 33 for rotating the display image. ing. Each button is an input unit for an operator to instruct the above-described rotation of the display image, and is connected to the image processing unit 16 and the image display element 22 via the CPU 10 (see FIG. 1).

  In addition, a projection unit 34 for displaying an image on an installation surface G such as a desk is provided in front of the projector 1.

  By operating the rotation instruction button 33, the display direction of the image can be changed (the display image is rotated by 180 degrees), so even if the observation position is the front side of the projector (see FIG. 6A), the rear side Even in this case (see FIG. 6B), the operator can view the display image from the viewing direction in which it should originally be viewed. Although some projectors can change the image display direction, the image display direction cannot be changed by a single operation as in this embodiment, and the operation is troublesome.

  9A is a diagram for explaining the rotation of the display image of the projector 1 according to the embodiment of the present invention, FIG. 9B is a diagram for explaining the relationship between the number of times the rotation instruction button 33 is pressed and the display image, and FIG. FIG. 5 is a diagram for explaining a display direction of an image on the image display element 22. In FIG. 9B, VH = 1 indicates that the display image is a vertical image, and VH = 0 indicates that the display image is a horizontal image.

  As described above, the image processing unit 16 can switch the vertical / horizontal display of the display image of the image data 19b or the image data 20b based on the control signal 10e from the CPU 10, and the image display element 22 controls the control signal from the CPU 10. The display image can be rotated 180 degrees based on 10e. As a result, the display image can be rotated every 90 degrees as shown in FIG. 9A. In the case of (a) and (c) of FIG. 9A, since the image in the vertical direction is displayed in the horizontally long display area PA, the image size of the display image is reduced, but the rotation instruction button 33 is operated. If the display image is rotated 90 degrees, the image is displayed in the entire display area PA as shown in FIGS. 9B and 9D. At this time, as shown in FIG. 10, the image displayed on the entire display area PA can be viewed by changing the orientation of the projector 1 or moving the observer. Since the image is displayed in the entire display area PA, the resolution of the display image becomes fine by using all the image display elements 22.

  FIG. 11 is a flowchart for explaining the operation of the projector 1 according to the embodiment of the invention. In FIG. 11, S21 to S30 indicate each processing step.

  The CPU 10 stores the values of control signals VH, UD, and LR transmitted to the image display element 22 as status flags (100 to 011).

  The CPU 10 determines the values of the control signals VH, UD, and LR to be transmitted to the image display element 22 by confirming the value of the state flag when the rotation instruction button 33 is pressed.

  Hereinafter, the operation of the projector 1 will be described with reference to FIGS.

  Each time the rotation instruction button 33 is pressed, the CPU 10 determines the state flag and determines the display state when the rotation instruction button 33 is pressed (S21, S25, S27, S29). At this time, if the status flag is “100”, the status is as shown in FIG. 9A (a). Similarly, if the status flag is “000”, the display status is FIG. 9A (b), if the status flag is “111”, the display status is FIG. 9A (c), and if the status flag is “011”, The display state is shown in FIG. 9A (d).

  When the rotation instruction button 33 is pressed (first time) and it is determined in S21 that the status flag is “100” (Yes), the current display state FIG. 9A (a) is changed to FIG. 9A (b). Therefore, the CPU 10 sets the control signals VH, UD, and LR to VH = 0, UD = 0, and LR = 0, respectively, and changes the status flag from “100” to “000” (S22).

  Next, the CPU 10 transfers the value (data) of the control signal VH to the image processing unit 16 (S23).

  Thereafter, the CPU 10 transfers the values (data) of the control signals UD and LR to the image display element 22 (S24).

  As a result, the display image is rotated 90 degrees clockwise to the state shown in FIG. 9A (b).

  When the rotation instruction button 33 is pressed again from the state shown in FIG. 9A (b) (second time), since the state flag is not “100” in S21 (No), the process proceeds to S25.

  If it is determined in S25 that the status flag is “000” (Yes), the CPU 10 changes the control signals VH, UD, LR to change the display status from FIG. 9A (b) to FIG. 9A (c). VH = 1, UD = 1, and LR = 1, respectively, and the status flag is changed from “000” to “111” (S26).

  Next, the CPU 10 transfers the value (data) of the control signal VH to the image processing unit 16 (S23).

  Thereafter, the CPU 10 transfers the values (data) of the control signals UD and LR to the image display element 22 (S24).

  As a result, the display image is rotated 90 degrees clockwise to the state shown in FIG. 9A (c).

  When the rotation instruction button 33 is pressed again from the state of FIG. 9A (c) (third time), the CPU 10 determines in S21 that the state flag is not “100” (No) and also in S25. Is determined not to be “000” (No), the process proceeds to S27.

  If it is determined in S27 that the status flag is “111” (Yes), the CPU 10 changes the control signals VH, UD, LR to change the display status from FIG. 9A (c) to FIG. 9A (d). VH = 0, UD = 1, and LR = 1, respectively, and the status flag is changed from “111” to “011” (S28).

  Next, the CPU 10 transfers the value (data) of the control signal VH to the image processing unit 16 (S23).

  Thereafter, the CPU 10 transfers the values (data) of the control signals UD and LR to the image display element 22 (S24).

  As a result, the display image is rotated 90 degrees clockwise to the state shown in FIG. 9A (d).

  When the rotation instruction button 33 is pressed again from the state of FIG. 9A (d) (fourth time), the CPU 10 determines that the status flag is not “100”, “000”, or “111” (S21, S25, In S27, both are determined as No), and the process proceeds to S29.

  If it is determined in S29 that the status flag is “011” (Yes), the CPU 10 changes the control signals VH, UD, and LR to change the display status from FIG. 9A (d) to FIG. 9A (a). VH = 1, UD = 0, and LR = 0, respectively, and the status flag is changed from “011” to “100” (S30).

  Next, the CPU 10 transfers the value (data) of the control signal VH to the image processing unit 16 (S23).

  Thereafter, the CPU 10 transfers the values (data) of the control signals UD and LR to the image display element 22 (S24).

  As a result, the display image is rotated 90 degrees clockwise to the state shown in FIG. 9A (a).

  Thereafter, when the rotation instruction button 33 is pressed again, the above process is repeated.

  Note that in the case of image data from the external interface 19A, the vertical position information for displaying the vertical image in the display area PA is not added, so that the image display element 22 or the image display driver 17 rotates only 180 degrees. Also, when the image data stored in the memory card 19B and the built-in memory 20 is moving image data, it does not have vertical position information, so that the image display element 22 is the same as in the case of image data input from the external interface 19A. Alternatively, only the image display driver 17 rotates 180 degrees.

  According to this embodiment, the display image is rotated in four ways every 90 degrees by combining the vertical / horizontal conversion of the display image by the image processing unit 16 and the rotation display of the display image by the image display element 22 every 180 degrees. Therefore, the display image can be projected in both the vertical position and the horizontal position according to the preference of the operator, and the display image can be easily viewed.

  In this embodiment, the reflective LCOS is used as the image display element 22, but a transmissive LCOS or DMD (Digital Micromirror Device) may be used instead. Further, the vertical position information of the image data stored in the memory card 19B and the built-in memory 20 is switched every time the rotation instruction button 33 is operated or when the operation is completed and the next image data is reproduced. It may be sometimes rewritten so that the image data is displayed in a desired display direction when it is next reproduced.

  Furthermore, in the above embodiment, image data taken with a digital camera is targeted, but a document file created by a personal computer or the like can also be targeted.

  In the above embodiment, the display states of FIGS. 3A and 3D, that is, the control signals UD and LR are rewritten between UD = 1, LR = 1 and UD = 0, and LR = 0, respectively. For example, when the direction in which the image display element 22 is incorporated into the projector housing 50 is upside down or when a mirror is disposed in the middle of the optical path, the display states of FIGS. 3B and 3C, that is, control The signals UD and LR may be rewritten between UD = 0, LR = 1 and UD = 1, and LR = 0, respectively.

  Further, the image data from the external interface 19A is not limited to an analog signal, and may be a digital signal input via a digital interface such as HDMI (High-Definition Multimedia Interface).

  Next, a conventional display image rotation method will be described as a comparative example.

  7A is a diagram for explaining the rotation of the display image of the projector according to the comparative example, FIG. 7B is a diagram for explaining the relationship between the number of presses of the rotation instruction button of the projector and the display image, and FIG. It is a flowchart explaining operation | movement. In FIG. 8, S11 to S15 indicate each processing step.

  The CPU determines the values of the control signals UD and LR to be transmitted to the image display element by checking the value of the state flag when the rotation instruction button is pressed. The control signal VH indicating the vertical and horizontal display directions is not involved in the rotation of the display image.

  Hereinafter, the operation of the projector will be described with reference to the flowchart of FIG.

  When the rotation instruction button is pressed once from the state of FIG. 7A (first time), the CPU determines whether or not the state flag is “00” (S11).

  When the status flag is “00” (Yes), the CPU sets the control signals UD and LR to UD = 1 and LR = 1, respectively, and changes the status flag from “00” to “11” (S12).

  Next, the CPU transfers the values (data) of the control signals UD and LR to the image display element (S13).

  As a result, the display image is rotated 180 degrees, and the state shown in FIG. 7A (b) is obtained.

  When the rotation instruction button is pressed again from the state of FIG. 7A (b) (second time), the CPU determines whether the state flag is “11” because the state flag is not “00” (No). (S14).

  When the status flag is “11” (Yes), the CPU sets the control signals UD and LR to UD = 0 and LR = 0, respectively, and changes the status flag from “11” to “00” (S15).

  Next, the CPU transfers the values (data) of the control signals UD and LR to the image display element (S13).

  As a result, the display image is rotated 180 degrees, and the state shown in FIG. 7A (a) is obtained.

  Thereafter, when the rotation instruction button is pressed again, the above process is repeated.

  Although the above description is for the control signal VH = 1 (vertical position shooting), the display image is rotated 180 degrees according to the flowchart even when the control signal VH = 0 (horizontal position shooting).

  As described above, rewriting of the control signals UD and LR only rotates the display image by 180 degrees, so only two display images can be obtained, and the image captured in the vertical position is displayed on the screen by the projector. In this case, a vertically long image is displayed in the horizontally long display area, and the image displayed in the display area is small and difficult to see.

  1: projector, 10: CPU (control unit), 12: main switch, 16: image processing unit, 17: image display driver, 22: image display element (image display unit), 30: menu button, 31a to 31d: movement Button, 32: determination button, 33: rotation instruction button.

Claims (6)

1st projection mode which can display the 1st image of the 1st image data acquired via an external interface, or 2nd projection mode which can display the 2nd image of the 2nd image data memorized by storage means In a projector capable of projecting
In the first projection mode, the first image to be displayed on the image display unit can be rotated 180 degrees, and in the second projection mode, the image processing unit can be instructed to switch between the vertical and horizontal display of the second image. And a control unit that outputs a control signal for rotating the second image displayed on the image display unit by 180 degrees.   The projector according to claim 1, wherein the control unit rotates the first and second images using a function of an image display driver.   The control unit determines a display direction of the second image based on vertical position information added to the second image data before instructing switching of the vertical and horizontal display of the second image. The projector according to claim 1 or 2.   The control unit does not instruct the image processing unit to switch between vertical and horizontal display of the second image when the second image data is moving image data to which the vertical position information is not added. The projector according to 1 or 2.   The projector according to claim 1, further comprising an operation member that instructs the control unit to rotate the first and second images.   The control unit stores vertical and horizontal information and vertical position information of the control signal as state flag values, and the image is based on the state flag value stored when the operation member is operated. The projector according to claim 1, wherein the value of the status flag transmitted to the display unit is rewritten.

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