JP2014062961A - Display device, projection device, display method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform suitable display with proper brightness without imposing a burden on user's eyes.SOLUTION: A display device includes: display systems 23 to 26, and 12 displaying images; an illuminance sensor 35 and an A/D conversion unit 33 measuring illuminance of environmental light; and a CPU 27 determining an increase speed of brightness when starting display of images with the display systems 23 to 26, and 12 on the basis of the measured illuminance, and controlling the brightness at the display systems 23 to 26, and 12 on the basis of the determined increase speed of brightness.

Description

  The present invention relates to a display device, a projection device, a display method, and a program suitable for a DLP (registered trademark) projector, for example.

  In order to eliminate the inconvenience that the display screen etc. becomes difficult to see when the ambient illuminance changes greatly instantaneously in a display device for car audio, etc., control is performed so that the light emission luminance corresponds to the changed environmental illuminance. Technology to do is considered. (For example, Patent Document 1)

JP 2011-028136 A

  Since the technique described in the above-mentioned patent document is a technique in which the light emission luminance is simply adjusted so as to correspond to the brightness after the change, for example, the process of changing the brightness of the environment is considered. There may be a situation where the user cannot cope with a rapid change in brightness.

  The present invention has been made in view of the above circumstances, and its object is to provide a display device and a projection that can perform suitable display with appropriate brightness without placing a burden on the eyes of the user. An apparatus, a display method, and a program are provided.

  According to one aspect of the present invention, a display unit that displays an image, an illuminance measurement unit that measures the illuminance of ambient light, and an illuminance measured by the illuminance measurement unit are used to start displaying an image on the display unit. It is characterized by comprising speed determining means for determining the brightness increasing speed and display control means for controlling the brightness in the display means based on the brightness increasing speed determined by the speed determining means.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to perform a suitable display with appropriate brightness, without putting a burden on a user's eyes.

1 is a perspective view showing an external configuration of a projector apparatus according to an embodiment of the present invention. FIG. 2 is a block diagram showing a configuration of a functional circuit of the projector device according to the embodiment. 6 is a flowchart showing detailed processing contents regarding light emission luminance and display gradation especially during power-on to power-off according to the embodiment. 6 is a flowchart showing detailed processing contents regarding light emission luminance and display gradation especially during power-on to power-off according to the embodiment. The figure explaining the control content with respect to the illumination intensity which concerns on the same embodiment. The figure explaining the control content with respect to the illumination intensity which concerns on the same embodiment. The figure which summarized the content of the control which concerns on the same embodiment simply. The figure which shows the structural example of the display apparatus which concerns on other embodiment of this invention.

  Hereinafter, an embodiment in which the present invention is applied to a DLP (Digital Light Processing) (registered trademark) projector apparatus will be described with reference to the drawings.

  FIG. 1 is a perspective view showing an external configuration of a projector apparatus 10 according to the present embodiment. As shown in FIG. 1, the projector device 10 includes a projection lens unit 12 and a distance measuring unit 13 on the front left end side of a rectangular parallelepiped main body casing 11.

  Similarly, a remote control light receiving unit 14 is provided near the left end of the front surface of the main body casing 11. The remote control light receiving unit 14 receives an infrared-modulated operation signal from a remote controller (not shown) dedicated to the projector device 10.

  Further, a large number of air holes 15, 15,... Are formed on the front surface of the main body casing 11 and the right side surface of the main body casing 11, as shown in the figure. Through these vent holes 15, 15,..., External air is taken in by driving a cooling fan disposed inside the main body casing 11, and heat generated by a light source or the like is efficiently discharged.

  Further, a speaker unit 16, a key input / indicator unit 17, and an illuminance detection unit 18 are provided on the upper surface of the main body casing 11. The speaker unit 16 outputs a sound corresponding to the sound signal input together with the image signal, an operation sound / warning sound corresponding to the operation state of the projector device 10, and the like.

  The key input / indicator unit 17 concentrates in the same area a key input unit having a key configuration similar to that of the above-described remote controller (not shown) and an indicator unit that performs lighting / flashing according to the operating state of the projector device 10. And arranged.

  The key input section of the key input / indicator section 17 has a key configuration such as a power key, a zoom up / down key, a focus up / down key, a menu key, a cursor key, and an enter key. The indicator part of the key input / indicator part 17 has an indicator lamp by LED (light emitting diode) such as a power supply pilot lamp and a light source temperature lamp.

  Further, although not shown in the figure, on the back surface of the main body casing 11 are input connectors for inputting various image signals, a USB terminal for connecting to a personal computer or a USB (Universal Serial Bus) memory, and the above-described remote control light receiving. A remote control light receiving unit similar to the unit 14 is provided.

  Further, the lower surface of the main casing 11 is provided with three or more legs including adjustment legs capable of adjusting the posture angle of the main casing 11.

Next, a schematic functional configuration of the projector device 10 will be described with reference to FIG.
The input unit 21 includes, for example, a video input terminal, an RGB input terminal, a VGA terminal, a USB terminal, and the like. The image signal input to the input unit 21 is digitized as necessary, and then sent to the image conversion unit 22 via the system bus SB.

  The image conversion unit 22 is also called a scaler, and unifies input image data into image data of a predetermined format suitable for projection and sends the image data to the projection processing unit 23.

  At this time, data such as symbols indicating various operating states for OSD (On Screen Display) including the point mark PT is also superimposed on the image data by the image conversion unit 22 as necessary, and the processed image data is projected. The data is sent to the processing unit 23.

  The projection processing unit 23 multiplies a frame rate in accordance with a predetermined format, for example, 120 [frames / second], the number of color component divisions, and the number of display gradations in accordance with the transmitted image data. The micromirror element 24 that is a display element (spatial light modulation element) is driven to display by the time-division driving.

  The micromirror element 24 has a plurality of, for example, WXGA (Wide extended Graphic Array) (horizontal 1280 pixels × vertical 800 pixels) tilt angles of micromirrors arranged in an array in the effective pixel region of the micromirror element. Each of the images is displayed by performing an on / off operation at a high speed, thereby forming an optical image with the reflected light.

  On the other hand, light of a plurality of colors including primary color lights of R, G, and B is sequentially emitted in a time division manner from the light source unit 25 in a time division manner. The light source unit 25 includes a semiconductor light emitting element such as an LD (semiconductor laser) and an LED (light emitting diode). The light from the light source unit 25 is totally reflected by the mirror 26 and applied to the micromirror element 24.

  Then, a light image corresponding to the color of the light source light is formed by the reflected light from the micromirror element 24, and the formed light image is projected onto a screen (not shown) to be projected through the projection lens unit 12. Is displayed.

  The CPU 27 controls all the operations of the above circuits. The CPU 27 is directly connected to the main memory 28 and the program memory 29. The main memory 28 is composed of, for example, an SRAM and functions as a work memory for the CPU 27. The program memory 29 is composed of an electrically rewritable nonvolatile memory, and stores an operation program executed by the CPU 27, various fixed data, and the like. The CPU 27 uses the main memory 28 and the program memory 29 to perform overall control operations in the projector device 10.

  The CPU 27 executes various projection operations according to key operation signals from the operation unit 30. The operation unit 30 includes the key input / indicator unit 17 provided in the main body of the projector device 10, the remote control light receiving unit 14 that receives infrared light from a remote controller (not shown) dedicated to the projector 1, and the like. Outputs a key operation signal based on a key operated by a key operation unit of the main body or a remote controller directly to the CPU 27.

The CPU 27 is further connected to an audio processing unit 31, an A / D conversion unit 32, and an A / D conversion unit 33 via the system bus SB. The sound processing unit 31 includes a sound source circuit such as a PCM sound source, converts the sound data given during the projection operation into an analog signal, drives the speaker unit 16 to emit a loud sound, or generates a beep sound or the like as necessary.
The A / D conversion unit 32 digitizes the detection signal from the distance measuring sensor 34 constituting the distance measuring unit 13 and outputs it to the CPU 27. The distance measuring sensor 34 includes, for example, a light emitting unit that emits infrared light in a direction parallel to the projection optical axis of the projection lens unit 12 and an infrared light receiving unit that faces in the same direction. The distance to the screen is measured by the time difference until.

  The A / D conversion unit 33 digitizes the detection signal from the illuminance sensor 35 constituting the illuminance detection unit 18 and outputs it to the CPU 27. The illuminance sensor 35 detects the illuminance of the environment where the main body casing 11 of the projector device 10 is installed as described above.

  Next, the operation of the above embodiment will be described.

  3 and 4 show the processing contents that the CPU 27 reads out the operation program stored in the program memory 29, develops it in the main memory 28, stores it, and executes it. Here, the contents relating to the control of the gradation luminance factor, which will be described later, of the light emission luminance at the light source unit 25 and the image displayed by the micromirror element 24 from the time of power-on to the time of power-off are mainly described.

  This operation program is prepared for a plurality of types of projector devices including different types of light source elements, including the projector device 10, and various parameter values specific to the model of the projector device 10 are also set. It is assumed that optimization for operating the projector device 10 is executed by storing the information.

  At the beginning of the processing, the CPU 27 is in a state where the power is cut off, and the CPU 27 repeatedly determines whether or not the power key for turning on the power is operated based on a key operation signal from the operation unit 30. The user waits for the user to turn on the power (step S101).

  When the power key is operated, the CPU 27 determines that in step S101, and executes initial processing including various initial settings for image projection, color wheel control unique to the DLP (registered trademark) system, and the like ( Step S102).

  Thereafter, the CPU 27 digitizes and inputs the detection output from the illuminance sensor 35 constituting the illuminance detection unit 18 installed on the upper surface of the main body casing 11 by the A / D conversion unit 33, and at that time, the projector device 10. The brightness of the ambient light in which is installed is measured (step S103).

  Here, the CPU 27 determines whether or not there is a possibility that glare will be given to the user at the start of light emission immediately after the start of the light emission immediately after the measurement result is equal to or less than the preset illuminance prescribed value Ies. (Step S104).

  When it is determined that the measurement result is larger than the illuminance regulation value Ies, the projector device 10 is installed in a relatively bright environment, and there is no possibility of giving glare to the user's eyes even immediately after the start of light emission. Then, the multiplication factor for the gradation of the image displayed by the micromirror element 24 (hereinafter referred to as “gradation multiplication factor”) is set as a value “1” that does not attenuate at all (step S117).

  When the gradation multiplier is 1, it is the same as the normal display. For example, when the gradation multiplier is 0.5, if the 256 gradation is 240, the display is actually performed. The gradation is displayed as 240 × 0.5 = 120.

  The gradation multiplier is used when the amount of light emitted from the projection lens unit 12 cannot be adjusted only by the light source unit 25 (details will be described later).

  In addition, the light source unit 25 is set to emit light under a predetermined condition that is rated so that no dimming process is performed (step S118).

  Thereafter, a normal projection operation accompanied by light emission from the light source unit 25 is executed under the above-described setting conditions (step S113), and a power key for turning off the power is again generated by a key operation signal from the operation unit 30. It is determined whether or not an operation has been performed (step S114).

  Here, when it is determined that the power key is not operated, the corresponding processing necessary for other projection operations (detailed explanation is omitted as it is not directly related to the present invention) is executed (step S115). ), The process returns to step S103.

  If it is determined in step S104 that the measured illuminance is less than or equal to the illuminance prescribed value Ies and there is a risk of glare to the user's eyes immediately after the start of light emission, the CPU 27 then uses the light source unit 25. The type of the element being used is determined (step S105).

  In addition, the CPU 27 measures the distance from the projection lens unit 12 to the screen on which the image is projected by the distance measuring sensor 34 constituting the distance measuring unit 13, and digitizes and acquires the measurement result by the A / D conversion unit 32. (Step S106).

  The CPU 27 determines a parameter for controlling the light control based on the element type of the light source thus obtained and the measured projection distance (step S107). Specific contents of the parameters include, for example, a set light amount, a gradual increase rate (a gradual increase amount per time), a gradual increase control allocation (presence / absence), and the like.

  Next, the CPU 27 determines from the light source element type determined in step S105 whether there is no light control restriction (step S108). This is for determining that the element is not difficult to adjust the light emission particularly in the low luminance region, such as an LD (semiconductor laser) and an LED (light emitting diode).

  A light-emitting element that does not have dimming restrictions can freely adjust the light source light amount from 0 to the maximum luminance, and can gradually increase the light source light amount from the lower limit (≈0) at the start of light emission.

  A light-emitting element having a light control restriction is one that can stably emit light only up to a certain low level light source light amount, and the light source light amount at the start of light emission is a predetermined light amount greater than zero.

  If it is determined that the element is not subject to dimming (step S108: Yes), then the CPU 27 is a value that does not attenuate the gradation multiplication factor for the image that the projection processing unit 23 drives with the micromirror element 24 at all. It is set as “1” (step S109).

  Thereafter, the CPU 27 sets the light emitting element in the light source unit 25 to emit light at the lower limit value of the luminance that can be emitted (step S110), and gradually increases the light source light amount according to the parameter value determined in step S107. The light source unit 25 is dimmed and controlled (step S111).

  The CPU 27 determines whether or not the light emission state of the light source unit 25 in which the light amount has been slightly increased by this gradual adjustment has reached a target value corresponding to the projection mode set at that time (step S112). If it is determined that it has not yet been reached, the process returns to step S111.

  In this way, the CPU 27 repeatedly executes the processes of steps S111 and S112, thereby gradually increasing the amount of light as needed until the light emission state at the light source unit 25 reaches the target value.

  Then, when the light emission state in the light source unit 25 reaches the target value, the CPU 27 determines that in step S112 and executes a normal projection operation (step S113).

  Thereafter, it is determined again whether or not a power key for turning off the power has been operated by a key operation signal from the operation unit 30 (step S114).

  If it is determined that the power key has not been operated, the corresponding processing necessary for other projection operations is executed (step S115), and the process returns to step S103 again.

FIG. 5 is a diagram for explaining the control contents with respect to the amount of light emitted from the projection lens unit 12 in the case of using a light emitting element of a type of light source that is not restricted by light control.
In FIG. 5, the left vertical axis indicates the light amount emitted from the projection lens unit 12 and the light amount of the light source unit 25, and the right vertical axis indicates the gradation multiplication factor.

  Also, the alternate long and short dash line indicates the light amount of the light source unit 25, the wavy line indicates the gradation multiplication factor, and the solid line indicates the light amount emitted from the projection lens unit 12 as a multiplication thereof.

  Here, in order to simplify the explanation, the case where there is no change in the illuminance on the screen surface at the time of projection is shown as an image in which the entire screen during normal projection is white.

  FIG. 5A shows the control content for the amount of light emitted from the projection lens unit 12 by the processing in steps S117, S118, and S113 when the brightness of the ambient light is greater than the preset illuminance prescribed value Ies. Represents.

  In this case, since there is no possibility of giving glare to the user's eyes, the brightness of the light source unit 25 is rapidly increased in the same manner as normal lighting from the start of light emission, and is stable at a steady point. The normal projection operation is started. The gradation multiplication factor may remain “1”.

  FIG. 5B shows an example of change in the amount of light II emitted from the projection lens unit 12 by the processing in steps S109 to S113 when the brightness of the ambient light is equal to or less than the preset illuminance prescribed value Ies (the environment is changed). An example of a moderately dark case) is shown.

  Here, since the light source unit 25 has no dimming restriction, the light amount emitted from the projection lens unit 12 can be changed only by the light amount of the light source unit 25. In the state in which the gradation multiplication factor Rgr is fixedly set to “1” from the beginning as indicated by the wavy line in the figure, the light source unit 25 emits light from the lower limit (≈0) during the initial adaptation period Tad. The light amount II emitted from the projection lens unit 12 gradually increases by starting and gradually increasing the light emission amount according to the set parameters.

  Then, when the adaptation period Tad ends when the amount of light emitted from the light emitting element reaches the target, the normal projection operation is performed thereafter, and the amount of light II emitted from the projection lens unit 12 serving as a reference is fixed.

  The adaptation time Tad is set in advance in consideration of a sufficient time required for the general human pupil to contract and adapt to the brightness of the environment.

  FIG. 5C shows an example of a change in the amount of light II emitted from the projection lens unit 12 (an example in the case where the environment is darker) by the processing of steps S109 to S113.

  Again, as indicated by the wavy line in the figure, with the gradation multiplication factor Rgr being fixedly set to “1” from the beginning, during the initial adaptation period Tad, the light source unit 25 has a lower dimming limit value ( The light emission is started from (≈0), and the light emission amount III emitted from the projection lens unit 12 gradually increases by gradually increasing the light emission amount according to the set parameters.

  When the adaptation period Tad ends when the amount of light emitted from the light emitting element reaches a target lower than the target value shown in FIG. 5B, the normal projection operation is performed thereafter, and the projection becomes a reference. The light quantity III emitted from the lens unit 12 is fixed.

  If it is determined in step S108 that there is a light control restriction based on the type of light source element (step S108: No), the amount of light emitted from the projection lens unit 12 is gradually increased from 0 with the light source unit 25 alone. Since the adjustment cannot be made, the control of the gradation multiplication factor is used together so that the amount of light emitted from the projection lens unit 12 is adjusted so as to gradually increase from 0 only by the light source unit 25.

  If it is determined in step S108 that there is a light control restriction based on the type of light source element (step S108: No), the CPU 27 then determines the target value of the light amount according to the projection mode set at that time. Then, it is determined whether or not the light amount is larger than the lower limit light amount of the light emitting element of the light source unit 25 capable of dimming (step S119).

  If it is determined that the target value of the light amount is larger than the lower limit light amount of the light emitting element of the light source unit 25 capable of dimming (step S119: Yes), the CPU 27 uses the floor at the micromirror element 24 by the projection processing unit 23. As the initial value, the multiplication factor is set to a value “0” which does not perform gradation display at all (the entire surface is displayed in black) (step S120).

  Next, the CPU 27 causes the light-emitting element of the light source unit 25 capable of dimming to emit light at the lower limit value (step S121).

  Further, the CPU 27 updates and sets the gradation multiplication factor so as to gradually increase the gradation multiplication factor by an increment value corresponding to the parameter value determined in the immediately preceding step S107 (step S122).

  The CPU 27 determines whether or not the gradation multiplication factor slightly increased by the gradual adjustment has reached 1, that is, whether or not the light amount has reached a lower limit value at which the light emitting element of the light source unit 25 can be dimmed. Judgment is made (step S123), and if not reached yet, the process returns to step S122 again.

  In this way, the CPU 27 repeatedly executes the processes of steps S122 and S123, so that the gradation multiplication factor is gradually increased as needed until the light quantity reaches a lower limit value that allows dimming of the light emitting elements of the light source unit 25.

  Then, when the gradation multiplication factor becomes “1”, the CPU 27 determines that in step S123, and then sets the light source unit 25 to gradually increase the light source light amount according to the parameter value determined in step S107. Dimming control is performed (step S124).

  The CPU 27 determines whether or not the light emission state of the light source unit 25 in which the light amount has been slightly increased by this gradual adjustment has reached a target value corresponding to the projection mode set at that time (step S125). If it is determined that it has not yet been reached, the process returns to step S124 again.

  In this way, the CPU 27 repeatedly executes the processes of steps S123 and S124, thereby gradually increasing the amount of light as needed until the light emission state at the light source unit 25 reaches the target value.

  When the light emission state in the light source unit 25 reaches the target value, the CPU 27 determines that in step S125, proceeds to the processing from step S113, and shifts to a normal projection operation.

FIG. 6 is a diagram for explaining the control content with respect to the amount of light emitted from the projection lens unit 12 when a light emitting element of a light source of a type having dimming restrictions is used.
In FIG. 6, as in FIG. 5, the left vertical axis represents the amount of light emitted from the projection lens unit 12 and the light amount of the light source unit 25, and the right vertical axis represents the gradation multiplier.

  Also, the alternate long and short dash line indicates the light amount of the light source unit 25, the wavy line indicates the gradation multiplication factor, and the solid line indicates the light amount emitted from the projection lens unit 12 as a multiplication thereof.

  Here, in order to simplify the description, the case where there is no change in the illuminance IV on the screen surface at the time of projection is illustrated as an image in which the entire screen during normal projection is white.

  FIG. 6A shows the projection lens unit 12 obtained by the processes in steps S117, S118, and S113 when the brightness of the ambient light is larger than the preset illuminance prescribed value Ies, as in FIG. 5A. The control content with respect to the quantity of emitted light is shown.

  In this case, since there is no possibility of giving glare to the user's eyes, the brightness of the light source unit 25 is rapidly increased in the same manner as normal lighting from the start of light emission, and is stable at a steady point. The normal projection operation is started. The gradation multiplication factor may remain “1”.

  When the brightness of the ambient light is larger than the preset illuminance regulation value Ies, the control for the amount of light emitted from the projection lens unit 12 has a light source of a type that does not have dimming restrictions and dimming restrictions. The same applies to the type of light source.

  FIG. 6B shows an example of change in the amount of light II emitted from the projection lens unit 12 by the processing in steps S120 to S125 when the brightness of the ambient light is equal to or less than the preset illuminance prescribed value Ies (the environment is changed). An example of a moderately dark case) is shown.

  In the state where the gradation multiplication factor Rgr is initially set to “0” as indicated by the wavy line in the figure, during the first adaptation period Tad, the light source unit 25 is initially set to a lower limit value that is the lower limit of dimming (a predetermined value greater than 0). The light intensity V emitted from the projection lens unit 12 is increased by gradually increasing the gradation multiplication factor from “0” to “1” while maintaining the light emission state. The light emitting element is gradually increased until it reaches the lower limit value that is the lower limit of light control.

  Then, with the gradation multiplier set to “1”, the gradation multiplier is set to “1” thereafter, and the emitted light quantity is gradually increased according to the set parameter to be emitted from the projection lens unit 12. Gradually increase the amount of light V.

  Thereafter, when the adaptation period Tad ends when the amount of light emitted from the light emitting element reaches the target, the normal projection operation is performed thereafter, and the amount of light V emitted from the projection lens unit 12 serving as a reference is fixed.

  In this way, the change in the amount of emitted light is changed by changing the gradation multiplication factor Rgr from 0 to 1 in a dark region where only the light source unit 25 is not dimmable, and the light source unit 25 is capable of dimming. In a bright region, the light intensity is changed by changing the light emission intensity of the light source unit 25.

  In this way, even the light source unit 25 with dimming restrictions can be appropriately adapted to adapt to the brightness of the environment.

  The amount of light V emitted from the projection lens unit 12 can be smoothly increased by continuously switching the control from the gradation multiplier to the control of the light emission intensity of the light source unit 25.

  If it is determined in step S119 that the target light amount is equal to or less than the lower limit light amount of the light emitting element of the light source unit 25 that can be adjusted (step S119: No), the CPU 27 performs the micromirror element 24 by the projection processing unit 23. As the initial value, the gradation multiplication factor at is set to a value “0” that does not perform gradation display at all (the entire surface is displayed in black) (step S126).

  Next, the CPU 27 causes the light-emitting element of the light source unit 25 capable of dimming to emit light at the lower limit value (step S121).

  Further, the CPU 27 updates and sets the gradation multiplication factor so as to gradually increase the gradation multiplication factor by an increment value corresponding to the parameter value determined in the immediately preceding step S107 (step S128).

  The CPU 27 determines whether or not the light emission state of the light source unit 25 has reached a target value corresponding to the projection mode or the like set at that time, based on the gradation multiplication factor slightly increased by this incremental adjustment. (Step S129) If it is determined that it has not yet been reached, the processing returns to the processing from Step S128 again.

  In this way, the CPU 27 repeatedly executes the processes of steps S128 and S129, so that the gradation multiplication factor is gradually increased from time to time within a range that does not become “1” until the light emission state at the light source unit 25 reaches the target value.

  When the light emission state in the light source unit 25 reaches the target value, the CPU 27 determines that in step S125, proceeds to the processing from step S113, and shifts to a normal projection operation.

  In such a case, the amount of light emitted from the projection lens unit 12 is controlled by changing only the gradation multiplier.

  FIG. 6C shows an example of a change in the amount of light VI emitted from the projection lens unit 12 by the processing in steps S126 to S129 when the brightness of the ambient light is equal to or less than the preset illuminance prescribed value Ies (the environment is changed). Example of darker case) is shown.

  As shown by the wavy line in the figure, the gradation multiplication factor Rgr is gradually increased from the initial “0”, and at the beginning of the first adaptation period Tad, the light source unit 25 is set at the lower limit value of light control (a predetermined value greater than 0). The light emission is started and the light emission state is maintained. On the other hand, due to the gradual increase of the gradation multiplication factor starting from “0”, the adaptation period Tad is reached when the light emission state at the light source unit 25 reaches the target value before the gradation multiplication factor becomes “1”. After that, the normal projection operation is performed, and the light amount VI emitted from the projection lens unit 12 serving as a reference is fixed.

  During the adaptation period Tad, a display image may be displayed as a white (gray) image or a dedicated logo image multiplied by the gradation multiplier, or input in the same way as during normal projection operation. An image obtained by multiplying the image based on the image signal input to the unit 21 by the gradation multiplier may be displayed.

  FIG. 7 simply summarizes the contents of the control according to the above embodiment. As shown in the figure, the variable α (0 <α <1) representing the light intensity multiplier on the light emitting element side of the light source unit 25 and the gradation multiplier of the image displayed by the micromirror element 24 as a display element are shown. Using the variable β (0 <β <1) to represent, the maximum light quantity to be irradiated is changed from “0 (zero)” to “1” which is the original image projection state, that is, the irradiation brightness is set to the maximum value. The adaptation time was changed according to the ambient illuminance.

  Here, the variable α representing the light intensity multiplier variable on the light emitting element side of the light source unit 25 is also shown to change to 1. However, depending on the environmental illuminance, the projection lens unit 12 serving as a reference in normal projection operation may be used. If it is desirable that the amount of emitted light is also dark, α is kept in a dimming state of less than 1.

  As described above, the amount of light emitted from the projection lens unit 12 is smoothly changed by switching the control of the gradation multiplier and the control of the light emission intensity of the light source unit 25 so that the continuity of the light amount is maintained. Can be raised.

  In this case, as described in the processing in steps S105 to S107 in FIG. 3, the light amount emitted from the projection lens unit 12 is gradually increased in consideration of the distance from the projection lens unit 12 of the projector device 10 to the projection target screen. The parameter for determining the amount of light is determined, and the amount of light corresponding to the distance and / or the change in the amount of light can be accurately reflected particularly when an image is projected.

  In the above embodiment, in order to simplify the explanation as shown in FIG. 5 and FIG. 6, the case where the amount of light emitted from the projection lens unit 12 obtained with the passage of time is changed into a polygonal line is taken as an example. As described above, it is assumed that the light control at the light emitting element of the light source unit 25 and the control in which the amount of light emitted from the projection lens unit 12 changes smoothly in a curved line or stepwise manner are executed. Also good.

  As described above in detail, according to the present embodiment, it is possible to perform suitable display with appropriate brightness without burdening the eyes of the user in consideration of ambient light.

  In the above embodiment, the parameter is determined so as to reduce the speed at which the amount of light on the light emission side increases as the illuminance of the ambient light is low. Therefore, the burden on the eyes of the user viewing the image according to the ambient light is reduced. Can be reliably reduced.

  Further, in the above embodiment, the maximum value of the light amount on the light emission side is determined in accordance with the illuminance of the environmental term. Therefore, even in a steady state, the burden on the eyes of the user who appreciates the image according to the environmental light. Can be reliably reduced.

  Further, in the above embodiment, it is determined whether or not the illuminance of the ambient light is higher than the preset illuminance specified value Ies. If the illuminance of the ambient light is higher than the illuminance specified value Ies, the light emission side is faster. Since the control method is adopted to increase the amount of light, if it is determined that there is no need to consider the burden on the user's eyes so much, the display immediately shifts to the display (projection) of a bright steady image. it can.

  Further, in the above embodiment, the light quantity emitted is adjusted by adjusting the gradation multiplication factor in the micromirror element 24 on the display element side, so that it is particularly difficult to adjust the luminance of the light emitting side element. Even if it exists, it can respond so that a user's eyes may not be burdened.

  In addition, in the above-described embodiment, since the luminance of the display unit is adjusted in combination with the adjustment of the light amount of the light source and the gradation multiplier, the burden on the user's eyes is not reduced by more precise control. I can respond.

  In the above-described embodiment, the amount of light emission on the light emitting element side is adjusted after controlling the gradation multiplier on the display element in the range of “0” to “1”. The level (quantization bit number) is not lowered, and it is possible to cope with the user's eyes with precise control.

  In the above-described embodiment, a display element that is not a self-luminous display element is used, such as the light source unit 25 and the micromirror element 24 that spatially modulates light from the light source unit 25 to form a light image. When displaying an image using this, it is determined whether or not the light source has a minimum light emission amount constraint. If so, the light source is made to emit light with the minimum light emission amount, and then the adaptive light emission amount is set. Since it is made to raise, it can respond so that a user's eyes may not be burdened in consideration of the kind of light source.

  On the other hand, when it is determined that the light source does not have the restriction on the minimum light emission amount, the light emission amount is linearly increased from the state of “0”, so that the light emission amount depends on the type of the light source. Without lowering the quantization level, it is possible to cope with a more dynamic load on the user's eyes.

  In the above embodiment, the case where the present invention is applied to the projector device has been described. However, unlike a display device that directly appreciates the display device, the amount of light emission is remarkably large, and the usage environment is in a dark place or similar. By using the above-described technology in a projection apparatus that is highly likely to be used in an environment, it is possible to cope with the burden on the eyes of the user as much as possible.

  As described above, the present invention can be similarly applied not only to a device that performs projection, but also to a display device in which a user views the display screen directly.

  FIG. 8 shows a configuration example when the display device is applied to, for example, a field sequential (color sequential) liquid crystal panel display 50. In the figure, reference numeral 51 denotes a transmission type monochrome liquid crystal panel, and an illuminance sensor 52 is disposed in the vicinity of the monochrome liquid crystal panel 51. Further, sheet-like backlight units 54B, 54R, and 54G are stacked on the lower surface side of the monochrome liquid crystal panel 51.

  Each of these backlight units 54B, 54R, 54G has LEDs (light emitting diodes) emitting B (blue) light, R (red) light, or G (green) light on four sides of a rectangular light guide diffuser plate. More precisely, a side-light unit is arranged in an array of lines.

  The primary color light generated by the surface emission emitted from the lower layer unit away from the monochrome liquid crystal panel 51 is transmitted through the upper layer unit, and the monochrome liquid crystal panel 51 is irradiated from the lower surface side. Accordingly, a light image matching the primary color light is formed by the image of the primary color light component displayed on the monochrome liquid crystal panel 51.

  Here, each primary color light emitted from the backlight units 54B, 54R, and 54G has, for example, a luminance (brightness) component in the order of B <R <G, and the primary color light having a higher luminance component is emitted from the lower layer side. By taking into account the amount of light that is attenuated when passing through a unit in the middle, the color balance when forming a primary color light image (modulating into a spatial image) on the monochrome liquid crystal panel 51 is taken. To do.

  The LCD drive unit 55 executes image display on the monochrome liquid crystal panel 51 and detection of illuminance information by driving the illuminance sensor 52. The LCD driver 55 also outputs to the backlight driver 56 a timing signal that matches the timing of the primary color image displayed on the monochrome liquid crystal panel 51 and a control signal that indicates the amount of light emission.

  The backlight driving unit 56 drives the backlight units 54B, 54R, and 54G cyclically in a time division manner according to the timing signal and the control signal from the LCD driving unit 55, and causes surface emission.

  For example, when one frame of a color image is composed of three fields of R, G, and B, the LCD driving unit 55 drives the monochrome liquid crystal panel 51 at a frame rate of, for example, 120 [frames / second] to display each primary color image. By displaying the image at a speed of 360 [field / second], the user of the liquid crystal panel display 50 can view the monochrome liquid crystal panel 51 from above, thereby allowing a color image without any sense of incongruity to be viewed.

  In the liquid crystal panel display 50 that is a kind of display device that directly views the monochrome liquid crystal panel 51 that is the display screen as described above, the detection result of the illuminance sensor 52 disposed in the vicinity of the monochrome liquid crystal panel 51 is reflected in the LCD. The drive unit 55 adjusts the amount of light emitted from the backlight units 54B, 54R, and 54G and the gradation multiplier for the gradation displayed on the monochrome liquid crystal panel 51 according to a control signal applied to the backlight drive unit 56. We can cope not to put burden on eyes.

  Furthermore, the present invention is not limited to the field sequential type liquid crystal panel display whose structure is illustrated in FIG. 8 above, but is arranged in parallel with a general display device that is not a field sequential type using other light sources, for example, a panel. The present invention can be similarly applied to a color liquid crystal display having a color filter, a liquid crystal projector, a plasma display, an SED rear projector type monitor device, and the like.

  In addition, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the invention in the implementation stage. Further, the functions executed in the above-described embodiments may be combined as appropriate as possible. The above-described embodiment includes various stages, and various inventions can be extracted by an appropriate combination of a plurality of disclosed constituent elements. For example, even if some constituent requirements are deleted from all the constituent requirements shown in the embodiment, if the effect is obtained, a configuration from which the constituent requirements are deleted can be extracted as an invention.

Hereinafter, the invention described in the scope of claims of the present application will be appended.
According to the first aspect of the present invention, when displaying an image on the display unit based on the illuminance measured by the display unit for displaying an image, the illuminance measurement unit for measuring the illuminance of ambient light, and the illuminance measurement unit. Speed determining means for determining the brightness increasing speed, and display control means for controlling the brightness of the display means based on the brightness increasing speed determined by the speed determining means.

  The invention described in claim 2 is characterized in that, in the invention described in claim 1, the speed determining means determines the brightness increasing speed smaller as the illuminance measured by the illuminance measuring means becomes darker.

  According to a third aspect of the present invention, in the first or second aspect of the present invention, the maximum brightness that is reached when the display means starts displaying an image based on the illuminance measured by the illuminance measurement means. The display device further includes a luminance determining unit, wherein the display control unit controls the luminance of the display unit so as to be the reached luminance determined by the reached luminance determining unit.

  The invention according to claim 4 is the invention according to any one of claims 1 to 3, further comprising first discriminating means for discriminating whether or not the illuminance measured by the illuminance measuring means is lower than a preset specified value. And the speed determining means has a predetermined adaptation in which the brightness gradually increases the brightness increasing speed at the start of image display when it is determined that the illuminance measured by the first determining means is lower than the specified value. When the illuminance measured by the first discriminating means is determined to be higher than the specified value, the luminance increase rate at the start of image display is larger than the adaptation increase rate, and the normal increase rate is determined. It is characterized by determining to.

  According to a fifth aspect of the present invention, in the invention according to any one of the first to fourth aspects, the display means displays a picture by modulating a light source that emits light for displaying an image and light from the light source. And a gradation multiplier adjusting means for controlling a gradation multiplier with respect to the gradation of the display element, wherein the display control means The luminance in the display means is controlled by controlling the gradation multiplication factor in the rate adjusting means.

  According to a sixth aspect of the present invention, in the fifth aspect of the present invention, the display control means is arranged such that the gradation multiplication factor until the luminance increases to a lower limit luminance that allows dimming of the light source. Then, the luminance of the light source is gradually increased to control the luminance of the display means.

  The invention according to claim 7 is the invention according to claim 6, wherein the display control means controls the gradation multiplication factor in a range of 0 to 1, and then gradually increases the light emission luminance of the light source. Features.

  The invention according to claim 8 is the invention according to claim 4, wherein the display means includes a light source that emits light for displaying an image, and a display element that displays light by modulating light from the light source. And further comprising: a second discriminating unit that discriminates whether or not the light source is a light source having a restriction on minimum lighting luminance, and the display control unit is configured such that the light source is the minimum light emission by the second discriminating unit. When it is determined that the light source has a luminance restriction, when starting to display an image, the light source emits light with the minimum light emission luminance, and then the luminance is increased based on the adaptation increase speed.

  According to a ninth aspect of the present invention, in the invention according to the eighth aspect, when the display control means determines that the light source is a light source that does not have a restriction on the minimum light emission brightness by the second determination means, the image When starting the display of the above, the luminance of the light source is increased from 0 (zero) luminance.

  According to a tenth aspect of the present invention, in the invention according to any one of the first to ninth aspects, the display means includes a projection mechanism that forms a light image and projects the light image outward.

  The invention according to claim 11 is the invention according to claim 10, further comprising distance measuring means for measuring the distance to the object on which the display means projects a light image, wherein the speed determining means is the illuminance measurement. Instead of the illuminance measured by the means, the brightness increasing speed when the display means starts displaying an image is determined based on the distance obtained by the distance measuring means.

  The invention according to claim 12 is a display method in an apparatus including a display unit that displays an image, and is based on the illuminance measurement step of measuring the illuminance of ambient light and the illuminance measured in the illuminance measurement step. A speed determining step for determining a luminance increase rate when starting display of an image on the display unit; and a display control step for controlling the luminance on the display unit based on the luminance increase rate determined in the speed determining step. It is characterized by that.

  A thirteenth aspect of the present invention is a program executed by a computer built in a device having a display unit for displaying an image, wherein the computer includes an illuminance measuring unit that measures the illuminance of ambient light, and the illuminance measuring unit. Based on the measured illuminance, speed determining means for determining the brightness increasing speed when image display is started on the display section, and controlling the brightness on the display section based on the brightness increasing speed determined by the speed determining means. It is made to function as a display control means to perform.

  DESCRIPTION OF SYMBOLS 10 ... Projector apparatus, 11 ... Main body casing, 12 ... Projection lens part, 13 ... Distance measuring part, 14 ... Remote control light-receiving part, 15 ... Air vent, 16 ... Speaker part, 17 ... Key input / indicator part, 18 ... Illuminance detection , 21 ... input unit, 22 ... image conversion unit, 23 ... projection processing unit, 24 ... micromirror element, 25 ... light source unit, 26 ... mirror, 27 ... CPU, 28 ... main memory, 29 ... program memory, 30 ... Operation unit 31 ... Audio processing unit 32 ... A / D conversion unit 33 ... A / D conversion unit 34 ... Distance sensor 35 ... Illuminance sensor 50 ... Liquid crystal panel display 51 ... Monochrome liquid crystal panel 52 ... Illuminance sensor, 54B, 54R, 54G ... backlight unit, 55 ... LCD drive unit, 56 ... backlight drive unit, SB ... system bus.

Claims (13)

Display means for displaying an image;
Illuminance measuring means for measuring the illuminance of ambient light;
Based on the illuminance measured by the illuminance measuring means, a speed determining means for determining a brightness increase speed when starting display of an image by the display means;
A display device comprising: display control means for controlling the brightness of the display means based on the brightness increasing speed determined by the speed determining means.   The display device according to claim 1, wherein the speed determining unit determines the brightness increasing rate to be smaller as the illuminance measured by the illuminance measuring unit is darker. Based on the illuminance measured by the illuminance measuring means, the display means further comprises an arrival luminance determining means for determining a maximum luminance that is reached when starting display of an image,
The display device according to claim 1, wherein the display control unit controls the luminance of the display unit so as to be the reached luminance determined by the reached luminance determining unit. A first determining means for determining whether the illuminance measured by the illuminance measuring means is lower than a preset specified value;
The speed determining means, when it is determined that the illuminance measured by the first determining means is lower than the specified value, the brightness increasing speed at the start of image display is changed to a predetermined adaptation increasing speed at which the brightness gradually increases. When it is determined that the illuminance measured by the first determination unit is higher than the specified value, the luminance increase rate at the start of image display is determined to be a normal increase rate larger than the adaptation increase rate. The display device according to claim 1, wherein the display device is a display device. The display means includes a light source that emits light for displaying an image, and a display element that displays an image by modulating light from the light source,
A gradation multiplication factor adjusting means for controlling a gradation multiplication factor with respect to the gradation of the display element;
The display control means controls the luminance on the display means by controlling the gradation multiplication factor in the gradation multiplication factor adjusting means with respect to the luminance increasing speed. The display apparatus in any one of thru | or 4.   The display control means controls the gradation multiplication factor until the luminance increasing speed reaches a lower limit luminance capable of dimming the light source, and then gradually increases the light emission luminance of the light source, 6. A display device according to claim 5, wherein the luminance of the display means is controlled.   The display device according to claim 6, wherein the display control unit controls the gradation multiplication factor in a range of 0 to 1 and then gradually increases the light emission luminance of the light source. The display means includes a light source that emits light for displaying an image, and a display element that displays an image by modulating light from the light source,
A second determining means for determining whether or not the light source is a light source having a minimum lighting luminance constraint;
In the case where the second determining unit determines that the light source is a light source having a minimum light emission luminance restriction, the display control unit causes the light source to emit light at the minimum light emission luminance when starting image display, and then The display device according to claim 4, wherein the luminance is increased based on an adaptation increase speed.   In the case where the second control unit determines that the light source is a light source that does not have a restriction on the minimum light emission luminance, the display control unit switches the light source from 0 (zero) luminance when starting the display of the image. The display device according to claim 8, wherein the luminance is increased.   The projection apparatus according to claim 1, wherein the display unit includes a projection mechanism that forms a light image and projects the light image toward the outside. The display means further comprises a distance measuring means for measuring a distance to a target on which the optical image is projected,
The speed determining means determines the brightness increasing speed when starting display of an image on the display means based on the distance obtained by the distance measuring means instead of the illuminance measured by the illuminance measuring means. The projection apparatus according to claim 10, wherein: A display method in an apparatus including a display unit for displaying an image,
An illuminance measurement process for measuring the illuminance of ambient light,
Based on the illuminance measured in the illuminance measurement step, a speed determination step for determining a luminance increase rate when starting display of an image on the display unit,
And a display control step of controlling the luminance on the display unit based on the luminance increase rate determined in the speed determination step. A program executed by a computer built in an apparatus having a display unit for displaying an image,
The above computer
Illuminance measuring means for measuring the illuminance of ambient light,
Based on the illuminance measured by the illuminance measuring means, a speed determining means for determining a brightness increasing speed when image display is started on the display section, and the display section based on the brightness increasing speed determined by the speed determining means A program which functions as a display control means for controlling the brightness of the screen.

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