JP2019121942A - Display device and control method of the same - Google Patents

Abstract

To provide a display device which can be suitably switched to a standby state in accordance with an environment where a projector 100 is installed.SOLUTION: A projector 100 comprising a light source part 190, comprises: a control part 170 controlling the light source part 190; and a sensor part 141 performing detection for an environment where the projector 100 is installed. The control part 170 can execute switching of a lighting state that the light source part 190 is lighted, a high speed activation standby state that a power consumption of the light source part 190 is smaller than the lighting state, and a normal standby state that the power consumption of the light source part 190 is smaller than the lighting state and the high speed activation standby state. The normal standby state is transferred to the high speed activation standby state as a trigger that a detection result of the sensor part 141 satisfies a prescribed condition.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a display device and a control method of the display device.

  Conventionally, a technique for switching between a plurality of standby states with different power consumption is known (see, for example, Patent Document 1). Patent Document 1 discloses a display device in which a user switches an external connection device between a normal standby mode in which the communication function is not limited and a power saving standby mode in which the communication function is limited.

JP, 2010-178249, A

Since the display device described in Patent Document 1 requires a user operation when switching the standby state, switching of the standby state may depend on the user's operation and may not be appropriately performed.
The present invention has been made in view of the above-described circumstances, and it is an object of the present invention to be able to switch the standby state appropriately according to the environment in which the display device is installed.

In order to solve the above-mentioned subject, the present invention is a display provided with a light source part, and is provided with a control part which controls the light source, and a detection part which detects to the environment where the display was installed. The control unit is configured to cause the light source unit to emit light, a first standby state in which the power consumption of the light source unit is smaller than the normal operation state, and the power consumption of the light source unit corresponds to the normal operation state and The second standby state smaller than the first standby state can be switched and executed, and the transition from the second standby state to the first standby state is triggered by the detection result of the detection unit satisfying a predetermined condition.
According to the present invention, the transition from the second standby state to the first standby state is triggered when the detection result of the detection unit satisfies the predetermined condition, so that the standby state is appropriately set according to the environment in which the display device is installed. Can be switched.

Further, in the present invention, in the first standby state, the light source unit can emit light in a shorter time than in the second standby state.
According to the present invention, since the light source unit can emit light in a shorter time than the second standby state in the first standby state, the standby state of the display device is set according to the environment in which the display device is installed. Can be promptly switched to a standby state in which the light source unit can emit light.

The present invention also includes an operation unit that receives a user's operation, and the control unit shifts to the normal operation state based on the operation received by the operation unit.
According to the present invention, since it is possible to shift to the first standby state according to the environment in which the display device is installed, the light source unit can be made to emit light promptly after receiving the user's operation.

Further, in the present invention, the control unit shifts from the first standby state to the second standby state, triggered by the detection result of the detection unit satisfying a predetermined condition.
According to the present invention, the transition from the first standby state to the second standby state is triggered when the detection result of the detection unit satisfies the predetermined condition, so that the power consumption is appropriately adjusted according to the environment in which the display device is installed. Can be suppressed.

Further, in the present invention, the detection unit is configured by at least one of a human sensor, a sound sensor, a temperature sensor, and an illuminance sensor.
According to the present invention, by detecting at least one of sound, presence / absence of a person, temperature, and illuminance, the standby state can be appropriately switched according to the environment in which the display device is installed.

Further, in the present invention, the detection unit is configured of a plurality of sensors, and the control unit shifts from the second standby state to the first standby state based on a detection result of any of the plurality of sensors. .
According to the present invention, in order to shift from the second standby state to the first standby state based on the detection result of any of the plurality of sensors, the standby state is switched more appropriately according to the environment in which the display device is installed. be able to.

Further, to solve the above problems, the present invention is a control method of a display device including a light source unit and a control unit that controls the light source unit, and the control unit causes the light source unit to emit light normally. The operating state, the first standby state in which the power consumption of the light source unit is smaller than the normal operating state, and the second standby state in which the power consumption of the light source unit is smaller than the normal operating state and the first standby state It is possible to detect an environment in which the display device is installed, and transition from the second standby state to the first standby state, triggered by the detection result satisfying a predetermined condition.
According to the present invention, the transition from the second standby state to the first standby state is triggered when the detection result of the detection unit satisfies the predetermined condition, so that the standby state is appropriately set according to the environment in which the display device is installed. Can be switched.

The figure which shows the structure of a projector. FIG. 7 is a diagram showing transitions of operating states of the projector. 6 is a flowchart showing the operation of the projector. FIG. 7 is a diagram showing transitions of operating states of the projector.

  FIG. 1 is a diagram showing the configuration of a projector 100 (display device).

  The projector 100 projects the image light onto the projection target to form an image based on the image data on the surface of the projection target. The projection target on which the projector 100 projects an image may be a flat surface or a curved surface or an uneven surface, but in the present embodiment, the case of projecting on a screen SC configured by a flat surface is exemplified. The screen SC may use a fixed flat surface such as a wall surface, or may be a curtain 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 incorporated in the projector 100 emits light.

The projector 100 includes an image input I / F unit 151. The image input I / F unit 151 includes a connector for connecting a cable and an interface circuit (all not shown).
The image input I / F unit 151 receives a signal transmitted from the outside. The image input I / F unit 151 extracts image data contained in the received signal and synchronization signals (vertical synchronization signal and horizontal synchronization signal). The image input I / F unit 151 outputs the extracted image data to the frame memory 153 so as to be stored in the frame memory 153, and outputs a synchronization signal to the image processing unit 155 and the control unit 170. The image processing unit 155 performs processing on image data in synchronization with the synchronization signal. Further, the control unit 170 controls the operation of each unit constituting the projector 100 based on the synchronization signal.

For the interface of the image input I / F unit 151, for example, the following interface can be used.
As an interface, HDMI (High-Definition Multimedia Interface), Displayport, MHL (Mobile High-definition Link (registered trademark), HDBaseT (registered trademark), Thunderbolt (registered trademark), USB Type-C, 3G- An interface that can digitally transmit a video signal and an audio signal such as SDI (Serial Digital Interface) can be used. Further, as the interface, an interface for data communication such as Ethernet (registered trademark), IEEE 1394, USB, or the like can be used. Alternatively, an analog video terminal such as an RCA terminal, a VGA terminal, an S terminal, or a D terminal may be provided in the outside and the projector 100 to transmit and receive an analog video signal.

  The projector 100 includes a light source unit 190, a projection unit 110 that forms an optical image and projects the image on the screen SC, and a drive unit 120 that drives the projection unit 110. The projection unit 110 includes a light source 111, a light modulator 112, and a projection optical system 113. Further, the drive unit 120 includes a light source drive unit 121, a light modulation device drive unit 122, and a projection optical system drive unit 123.

The light source unit 190 includes a light source 111 and a light source driving unit 121.
The light source 111 is configured of, for example, a laser light source. The light source 111 receives supply of power from the light source drive unit 121 to emit light.
The light source driving unit 121 is connected to the bus 180, and controls the power supply to the light source 111 according to the control of a control unit 170 (described later) connected to the bus 180 to turn on or off the light source 111. The light source drive unit 121 receives power supply from the power supply unit 200 and drives it.
The light source unit 190 may include a reflector and an auxiliary reflector for guiding the light emitted by the light source 111 to the light modulation device 112. Furthermore, the light source unit 190 is a lens group for enhancing the optical characteristics of the projection light, a polarizing plate, or a light control element for reducing the light quantity of the light emitted by the light source 111 on the path to the light modulation device 112 ) May be provided.

  The light modulator 112 includes, for example, three liquid crystal panels corresponding to the three primary colors of RGB. The light emitted from the light source 111 is separated into three color light of RGB by a dichroic mirror, a reflection mirror, a relay lens and the like (all not shown), and is incident on the liquid crystal panel of the corresponding color. The three liquid crystal panels are transmissive liquid crystal panels, and modulate light to be transmitted to generate image light. The image light passing through each liquid crystal panel and modulated is combined by a combining optical system such as a cross dichroic prism and the like, and is emitted to the projection optical system 113.

The light modulation device 112 is driven by the light modulation device drive unit 122. The light modulation device drive unit 122 is connected to the bus 180 and drives the light modulation device 112 according to the control of the control unit 170.
The light modulation device drive unit 122 generates drive signals for driving the liquid crystal panel for each of the R, G, and B colors based on the image data input from the image processing unit 155. The light modulation device drive unit 122 drives the liquid crystal panel of the corresponding color based on the generated R, G, and B drive signals, and draws an image on each liquid crystal panel.

  The projection optical system 113 includes a lens group that projects the image light modulated by the light modulation device 112 in the direction of the screen SC to form an image on the screen SC. In addition, the projection optical system 113 may include a zoom mechanism that performs enlargement / reduction and focus adjustment of the projection image of the screen SC, and a focus adjustment mechanism that performs focus adjustment.

  The projection optical system 113 is driven by the projection optical system drive unit 123. The projection optical system drive unit 123 includes, for example, a motor, and drives the motor according to the control of the control unit 170 to adjust zoom and focus.

  The projector 100 includes an operation unit. The operation unit includes an operation panel 131, a remote control light receiving unit 133, and an input / output I / F unit 135.

  The operation panel 131 functioning as a user interface is provided with various operation keys and a liquid crystal panel. The input / output I / F unit 135 is connected to the operation panel 131, the remote control light receiving unit 133, and the bus 180. When the operation key is operated, the input / output I / F unit 135 outputs an operation signal corresponding to the operated operation key to the control unit 170. Further, the input / output I / F unit 135 causes the liquid crystal panel to display various operation screens under the control of the control unit 170. Various buttons capable of operating the projector 100 are displayed on the operation screen.

  The remote control light receiving unit 133 that receives an infrared signal receives an infrared signal transmitted from the remote control 5 that functions as a user interface. The remote control light receiving unit 133 decodes the received infrared signal, generates an operation signal indicating the operation content of the remote control 5, and outputs the operation signal to the control unit 170.

  The projector 100 includes an imaging unit 140. The imaging unit 140 includes an imaging optical system, an imaging element such as a CCD (Charge Coupled Device) or a CMOS (Complementary MOS), and an interface circuit. The imaging device may be configured to be capable of measuring Y (brightness) of XYZ tristimulus values, or may be capable of measuring color components of general RGB colors. The imaging unit 140 images the projection direction of the projection optical system 113 according to the control of the control unit 170. The imaging range of the imaging unit 140, that is, the angle of view is a range including the screen SC and its peripheral portion. The imaging unit 140 outputs the captured image data to the control unit 170.

  The projector 100 includes a sensor unit 141 (detection unit). The sensor unit 141 of the present embodiment is configured of a human sensor (sensor). The human sensor detects the presence or absence of the user around the projector 100 by, for example, infrared rays or ultrasonic waves. Here, the surrounding is a detection range that can be detected by the human sensor. In the present embodiment, the detection of the presence or absence of the user around the projector 100 corresponds to the detection of the environment in which the projector 100 is installed. The sensor unit 141 outputs, for example, detection results with different values to the control unit 170 via the bus 180 according to the presence or absence of the user. The control unit 170 executes a process according to the detection result input from the sensor unit 141.

  The projector 100 includes a communication I / F unit 145. The communication I / F unit 145 transmits and receives various data to and from other projectors according to the control of the control unit 170. The various data transmitted and received by the communication I / F unit 145 include control information for controlling other projectors, responses of the other projectors to the control information, and the like.

The projector 100 includes a power supply unit 200. The power supply unit 200 is connected to the commercial AC power supply DG via a cable, and generates power to drive the projector 100 based on the power supplied from the commercial AC power supply DG. Also, the power supply unit 200 supplies the generated power to each unit of the projector 100 including the power supply unit 201.
The power supply unit 201 is connected to the bus 180, and controls the power supply from the power supply unit 200 to the light source drive unit 121 according to the control of the control unit 170 which is also connected to the bus 180.

  The projector 100 includes an image processing system. The image processing system is mainly configured of a control unit 170 that centrally controls the entire projector 100, and further includes a frame memory 153, an image processing unit 155, and a storage unit 160. The control unit 170, the image processing unit 155, and the storage unit 160 are communicably connected to each other via the bus 180.

  The frame memory 153 comprises a plurality of banks. Each bank has a storage capacity capable of writing one frame of image data. The frame memory 153 is configured by, for example, an SDRAM (Synchronous Dynamic Random Access Memory). The SDRAM is a DRAM that reads and writes data in synchronization with a clock.

The image processing unit 155 performs, for example, resolution conversion (scaling) processing or resizing processing, distortion correction, shape correction processing, digital zoom processing, adjustment of color tone and brightness of an image, to the image data expanded in the frame memory 153. And so on. The image processing unit 155 executes the processing specified by the control unit 170, and performs processing using the parameters input from the control unit 170 as necessary. Also, the image processing unit 155 can, of course, be executed by combining a plurality of the above processes.
The image processing unit 155 reads out the image data whose processing has been completed from the frame memory 153 and outputs the image data to the light modulation device driving unit 122.

  The storage unit 160 is, for example, an auxiliary storage device such as a hard disk drive. The storage unit 160 is replaced by a semiconductor memory such as flash memory or EEPROM (Electrically Erasable Programmable ROM) or an optical disc such as a CD (Compact Disc), a DVD (Digital Versatile Disc), a BD (Blu-ray (registered trademark) Disc) or the like. It is possible. The storage unit 160 stores various data such as a control program executed by the control unit 170 and parameters used for image processing executed by the image processing unit 155. The storage unit 160 also stores image data. The projector 100 reads image data from the storage unit 160, processes the image data, and projects the processed image data onto the screen SC by the projection unit 110.

  The control unit 170 includes a CPU, a ROM, a RAM, and other peripheral circuits (all not shown) as hardware. The CPU is a processor that executes arithmetic processing, and executes arithmetic processing in accordance with a control program stored in the ROM or the storage unit 160. The ROM is a non-volatile memory, and stores, for example, a control program and operation data. The RAM is used as a work area for temporarily storing control programs and arithmetic data to be executed by the processor.

  In the present embodiment, the control unit 170 includes one processor (CPU), and the processor executes processing according to the control program to realize the function of the control unit 170. However, control is performed by a plurality of processors or semiconductor chips. The function of unit 170 may be realized. For example, the control unit 170 further includes a co-processor such as a system-on-a-chip (SoC), a micro control unit (MCU), or a field-programmable gate array (FPGA). It is also good. Further, the control unit 170 may perform various controls by causing both of the CPU and the sub-processing apparatus to cooperate or selectively using one of the two.

  The control unit 170 includes, as functional blocks, a projection control unit 171, a power supply control unit 172, a condition satisfaction determination unit 173, and a state transition control unit 174. These functional blocks conveniently show functions realized by the CPU executing arithmetic processing in accordance with the control program as blocks, and do not indicate specific application software or hardware.

  The projection control unit 171 controls the image processing unit 155 and the drive unit 120 to project an image on the screen SC. Specifically, the projection control unit 171 controls the image processing unit 155 to cause the image processing unit 155 to process the image data expanded in the frame memory 153. At this time, the projection control unit 171 reads parameters required for processing by the image processing unit 155 from the storage unit 160 and outputs the parameters to the image processing unit 155.

  In addition, the projection control unit 171 controls the light source driving unit 121 to turn on the light source 111 of the light source unit 190 and to adjust the luminance of the light source that is turned on. Furthermore, the projection control unit 171 controls the light modulation device drive unit 122 to cause the liquid crystal panel of the light modulation device 112 to draw an image. Further, the projection control unit 171 controls the projection optical system drive unit 123 to drive a motor, and adjusts the zoom and focus of the projection optical system 113.

  The power supply control unit 172 controls the power supply unit 201 based on the input from the state transition control unit 174, and controls the power supply state of the power supply unit 201 to the light source drive unit 121. The power supply control unit 172 switches the power supply state of the power supply unit 201 to either the supply state or the stop state. The supply state is a state in which the power supply unit 201 supplies power to the light source drive unit 121. In the stop state, the power supply unit 201 stops the power supply to the light source drive unit 121.

The condition satisfaction determination unit 173 determines whether the detection result input from the sensor unit 141 satisfies a predetermined condition. In the present embodiment, the condition satisfaction determination unit 173 detects that the detection result input from the sensor unit 141 indicates that the user is not present around the projector 100 when the operation state of the projector 100 is in the high speed start standby state 100B. It is determined whether it is a result (hereinafter referred to as "a user non-detection result"). In this determination, that the detection result satisfies the predetermined condition indicates that the detection result is a user non-detection result. In addition, when the operation state of the projector 100 is in the normal standby state 100C, the condition satisfaction determination unit 173 detects that the detection result input from the sensor unit 141 indicates that the user is around the projector 100 (hereinafter referred to as It is determined whether or not it is expressed as "user-presented detection result". In this determination, that the detection result satisfies the predetermined condition indicates that the detection result is a user presence detection result.
The condition satisfaction determination unit 173 outputs the determination result to the state transition control unit 174.

The state transition control unit 174 controls switching of the operation state of the projector 100.
In the present embodiment, the operation state of the projector 100 includes the lighting state 100A (normal operation state) (see FIG. 2), the high-speed start standby state 100B (first standby state) (see FIG. 2), and the normal standby state 100C (see FIG. 2). There are three states: second standby state) (see FIG. 2).

The lighting state 100A is an operation state in which the light source 111 emits light and an image can be projected onto a projection target such as the screen SC.
The high-speed start-up standby state 100B is a standby state in which the light source 111 is waiting for light emission. In the high-speed start-up standby state 100B, power is not supplied to the light source 111 and the light source 111 is turned off, and the power consumption of the light source unit 190 is smaller than that of the lighting state 100A. In the high-speed start-up standby state 100B, power is supplied to the light source drive unit 121, and the light source drive unit 121 can be driven. Therefore, the high-speed start-up standby state 100B is an operation state in which the light source 111 can emit light in a shorter time than the normal standby state 100C by the start-up time of the light source drive unit 121.
The normal standby state 100C is a standby state in which light emission of the light source 111 is on standby, and no power is supplied to any of the light source 111 and the light source drive unit 121. Therefore, the normal standby state 100C is an operating state in which the power consumption of the light source unit 190 is smaller than that in the high-speed start-up standby state 100B.

  The state transition control unit 174 switches the lighting state 100A, the high speed start standby state 100B, and the normal standby state 100C as shown in FIG. 2 to change the operation state of the projector 100.

  FIG. 2 is a diagram showing the transition of the operation state of the projector 100. As shown in FIG.

  As shown in FIG. 2, when the operation transition state of the projector 100 is the high speed start standby state 100B as shown in FIG. 2, when the first transition trigger instructing the transition to the lighting state 100A occurs, the high speed start standby The state 100B is shifted to the lighting state 100A (step ST1). The operation of the state transition control unit 174 in step ST1 will be described later. As the first transition trigger, the operation unit receives an operation instructing the lighting of the light source 111 by the operation of the remote control 5 or the operation panel 131 by the user, or the image input I / F unit 151 receives image data from the outside Can be mentioned.

  When the second transition trigger for instructing transition to the high speed start standby state 100B occurs in the state transition control unit 174 when the operation state of the projector 100 is the light on state 100A, the light state 100A changes to the high speed start standby state 100B. A transition is made (step ST2). The operation of the state transition control unit 174 in step ST2 will be described later. As the second transition trigger, the operation unit receives an operation instructing the light source 111 to turn off by the operation of the remote control 5 or the operation panel 131 by the user, or the output of the image data from the image processing unit 155 for a predetermined period And the like.

  When the operation transition state of the projector 100 is the high-speed start standby state 100B, the state transition control unit 174 generates a third transition trigger instructing transition to the normal standby state 100C, the high-speed start standby state 100B starts the normal standby state. It shifts to 100C (step ST3). The third transition trigger and the operation of the state transition control unit 174 in step ST3 will be described later.

  When the operation transition state of the projector 100 is the normal standby state 100C and the fourth transition trigger instructing the transition to the high speed start standby state 100B occurs, the state transition control unit 174 changes from the normal standby state 100C to the high speed start standby state It shifts to 100 B (step ST4). The fourth transition trigger and the operation of the state transition control unit 174 in step ST4 will be described later.

As described above, the state transition control unit 174 switches the operation state of the projector 100 to any of the lighting state 100A, the high-speed start standby state 100B, and the normal standby state 100C based on the occurrence of the trigger.
In particular, the state transition control unit 174 performs switching between the high-speed startup standby state 100B and the normal standby state 100C as follows, so that switching between standby states appropriate for the environment in which the projector 100 is installed can be performed. Make it

  FIG. 3 is a flowchart showing the operation of the projector 100.

  At the start of the flowchart illustrated in FIG. 3, it is assumed that the operating state of the projector 100 is the lighting state 100A.

  As shown in FIG. 3, the state transition control unit 174 of the control unit 170 of the projector 100 determines whether a second transition trigger has occurred (step SA1). When the state transition control unit 174 determines that the second transition trigger is not generated (step SA1: NO), the operation state of the projector 100 is not moved from the lighting state 100A to another operation state, and step SA1 is performed again. Execute the process of

  On the other hand, when determining that the second transition trigger has occurred (step SA1: YES), the state transition control unit 174 causes the operating state of the projector 100 to transition from the lighting state 100A to the high speed startup standby state 100B (step SA2). . In step SA2, the state transition control unit 174 controls the light source drive unit 121 to stop the power supply from the light source drive unit 121 to the light source 111 and turn off the light source 111.

  When the state transition control unit 174 shifts the operation state of the projector 100 to the high speed start standby state 100B, the condition satisfaction determination unit 173 determines whether the detection result input from the sensor unit 141 is the user non-detection result. It discriminates (step SA3).

  When the condition satisfaction determination unit 173 determines that the detection result input from the sensor unit 141 is not the user non-detection result (step SA3: NO), in other words, the detection result input from the sensor unit 141 is the user presence detection result. If it is determined that there is, the state transition control unit 174 determines whether or not the first transition trigger has occurred (step SA4). When the state transition control unit 174 determines that the first transition trigger is not generated (step SA4: NO), processing is performed without moving the operating state of the projector 100 from the high speed startup standby state 100B to another operating state. Is returned to step SA3. On the other hand, when determining that the first transition trigger has occurred (step SA4: YES), the state transition control unit 174 causes the operation state of the projector 100 to transition from the high speed start standby state 100B to the lighting state 100A (step SA5). In step SA5, the state transition control unit 174 controls the light source drive unit 121 to supply power from the light source drive unit 121 to the light source 111 to light the light source 111.

  Returning to the description of step SA3, when the condition satisfaction determination unit 173 determines that the detection result input from the sensor unit 141 is the user non-detection result (step SA3: YES), the state transition control unit 174 The operating state is shifted from the high speed start standby state 100B to the normal standby state 100C (step SA6). That is, the state transition control unit 174 causes the transition from the high-speed start standby state 100B to the normal standby state 100C, with the third transition trigger that the sensor unit 141 detects that the user is not present around the projector 100. In step SA7, the power supply control unit 172 controls the power supply unit 201 to stop the power supply to the light source drive unit 121.

  The situation where there is no user around the projector 100 is a situation where the probability that the projector 100 is used (including projection) is low. Therefore, the control unit 170 shifts the operation state of the high-speed start standby state 100B to the normal standby state 100C in response to the occurrence of the third trigger. Thus, the control unit 170 can switch to a standby state in which power consumption is small when there is no user around the projector 100, and unnecessary power consumption can be suppressed.

  When the state transition control unit 174 shifts the operation state of the projector 100 to the normal standby state 100C, the condition satisfaction determination unit 173 determines whether the detection result input from the sensor unit 141 is a user presence detection result ((1) Step SA7).

  When the condition satisfaction determination unit 173 determines that the detection result input from the sensor unit 141 is not the user presence detection result (step SA7: NO), in other words, the detection result input from the sensor unit 141 is the user non-detection result. If it is determined that there is, the state transition control unit 174 continues the process of step SA7 without shifting the operation state of the projector 100 from the normal standby state to another operation state. Accordingly, when there is no user around the projector 100, the control unit 170 can suppress the power consumption of the projector 100. That is, the control unit 170 can switch to an appropriate standby state according to the environment in which the projector 100 is installed.

  On the other hand, when the condition satisfaction determination unit 173 determines that the detection result input from the sensor unit 141 is the user presence detection result (step SA7: YES), the state transition control unit 174 sets the operation state of the projector 100 to normal. The standby state 100C is shifted to the high speed start standby state 100B (step SA8). That is, the state transition control unit 174 causes the sensor unit 141 to use the fourth transition trigger as the presence of the user around the projector 100, and causes the normal standby state 100C to transition to the high speed startup standby state 100B. In step SA9, the power supply control unit 172 controls the power supply unit 201 to supply power to the light source drive unit 121.

  The situation in which the user is present around the projector 100 is a situation in which the projector 100 is highly likely to be used (including projection) by the user. Therefore, in such a situation, although the power consumption is higher than that in the normal standby state 100C, it is assumed that it is more convenient for the user to be able to emit the light of the light source 111 promptly. Therefore, when the operation state of the projector 100 is in the normal standby state 100C, the control unit 170 shifts from the normal standby state 100C to the high-speed start standby state 100B triggered by the occurrence of the fourth trigger. Accordingly, when the user is around the projector 100, the control unit 170 can promptly set the operation state of the projector 100 to a state in which the light source 111 can emit light. That is, the control unit 170 can switch to an appropriate standby state according to the environment in which the projector 100 is installed.

  As described above, when determining that the first transition trigger has occurred, the control unit 170 causes the operating state of the projector 100 to transition from the high speed start standby state 100B to the lighting state 100A. Therefore, when there is a user around the projector 100, the control unit 170 can cause the light source 111 to emit light promptly after receiving the user's operation by setting the operation state of the projector 100 to the high speed start standby state 100B. .

  In the above, the case where sensor part 141 was constituted by a human sensor was illustrated. However, the configuration of the sensor unit 141 is not limited to the human sensor. For example, it may be configured by the following sensors.

  For example, the sensor unit 141 may be configured by a sound sensor (sensor). The sound sensor is, for example, a sound collection device such as a microphone, and collects sound around the projector 100. Here, the surrounding is a range where the sound sensor can pick up sound. The sound sensor picks up sound around the projector 100 as a detection for the environment where the projector 100 is installed, and outputs sound data indicating the picked-up sound as a detection result to the control unit 170.

When the sensor unit 4 is configured by a sound sensor, the condition satisfaction determination unit 173 determines that the sound data input from the sound sensor falls below a predetermined volume when the operation state of the projector 100 is the high speed start standby state 100B. It is judged whether or not it is voice data (corresponding to a user non-detection result) indicating. In this determination, the condition that the detection result satisfies the predetermined condition indicates that the sound data input from the sound sensor, which is the detection result, is sound data indicating sound falling below a predetermined volume. The state transition control unit 174 switches the operation state of the projector 100 to the normal standby state 100C when it is determined that the sound data input from the sound sensor is sound data indicating sound below a predetermined volume.
When the sensor unit 4 is configured by a sound sensor, the condition satisfaction determination unit 173 determines that the sound data input from the sound sensor is greater than or equal to a predetermined volume when the operation state of the projector 100 is the normal standby state 100C. It is determined whether it is voice data (corresponding to a user presence detection result) indicating voice. In this determination, the condition that the detection result satisfies the predetermined condition indicates that the sound data input from the sound sensor, which is the detection result, is sound data indicating sound of a predetermined volume or more. The state transition control unit 174 switches the operation state of the projector 100 to the high-speed start standby state 100B when it is determined that the sound data input from the sound sensor is sound data indicating sound of a predetermined volume or more.

  In the situation where there is no user around the projector 100, it is assumed that the sound around the projector 100 is lower than when there are users. In the situation where there is no user around the projector 100, the opposite is true. Therefore, as described above, the control unit 170 achieves the same effect as the case where the sensor unit 141 is configured by a human sensor by switching between the high-speed start standby state 100B and the normal standby state 100C.

  Also, for example, the sensor unit 141 may be configured by an illuminance sensor (sensor). The illuminance sensor is disposed at a position exposed on the surface of the housing of the projector 100, and detects the illuminance of light on the projector 100. The illuminance sensor detects the illuminance of light on the projector 100 as a detection for the environment where the projector 100 is installed, and outputs the detection result to the control unit 170.

When the sensor unit 141 is configured by an illuminance sensor, the condition satisfaction determination unit 173 determines that the detection result input from the illuminance sensor is less than a predetermined illuminance when the operation state of the projector 100 is the high speed start standby state 100B. It is determined whether it is a detection result (corresponding to a user non-detection result) indicating. In this determination, that the detection result satisfies the predetermined condition indicates that the illuminance indicated by the detection result is a detection result lower than the predetermined illuminance. The state transition control unit 174 switches the operation state of the projector 100 to the normal standby state 100C when it is determined that the detection result input from the illuminance sensor is a detection result that falls below a predetermined illuminance.
When the sensor unit 4 is configured by an illuminance sensor, the condition satisfaction determination unit 173 determines that the detection result input from the illuminance sensor is equal to or higher than a predetermined illuminance when the operation state of the projector 100 is in the normal standby state 100C. It is determined whether or not the detection result indicates the illuminance (corresponding to the user presence detection result). In this determination, that the detection result satisfies the predetermined condition indicates that the illuminance sensor indicated by the detection result is a detection result indicating a predetermined illuminance or higher. The state transition control unit 174 switches the operation state of the projector 100 to the high-speed start standby state 100B when determining that the detection result input from the illuminance sensor is a detection result indicating the illuminance equal to or higher than the predetermined illuminance.

  Although depending on the use mode of the projector 100, it is assumed that the illuminance of light to the projector 100 is low in a situation where there is no user around the projector 100 as compared with the case where the user is present. On the other hand, in a situation where a user is present around the projector 100, it is assumed that the illuminance of light on the projector 100 is high at least before the use of the projector 100 as compared to the case where no user is present. Therefore, as described above, the control unit 170 achieves the same effect as the case where the sensor unit 141 is configured by a human sensor by switching between the high-speed start standby state 100B and the normal standby state 100C.

  Also, for example, the sensor unit 141 may be configured by a temperature sensor (sensor). The temperature sensor is disposed at a position exposed on the surface of the housing of the projector 100, and detects the temperature of the environment in which the projector 100 is installed. The temperature sensor detects an environmental temperature at which the projector 100 is installed as a detection for the environment where the projector 100 is installed, and outputs a detection result to the control unit 170.

  When the sensor unit 141 is configured by a temperature sensor, the condition satisfaction determination unit 173 determines similarly to the case where the sensor unit is configured by an illuminance sensor. Further, the state transition control unit 174 switches between the high-speed start standby state 100B and the normal standby state 100C, as in the case where the sensor unit is configured by the illuminance sensor.

  Although depending on the use mode of the projector 100, when there is no user around the projector 100, the environmental temperature at which the projector 100 is installed may be lower than when there are users. On the other hand, when the user is around the projector 100, the environmental temperature at which the projector 100 is installed may be higher than when there is no user due to the user's body temperature or room temperature. Therefore, as described above, the control unit 170 achieves the same effect as the case where the sensor unit 141 is configured by a human sensor by switching between the high-speed start standby state 100B and the normal standby state 100C.

  In the above, the case where sensor part 141 was constituted by either a human sensor, a sound sensor, an illumination sensor, and a temperature sensor was illustrated. However, the sensor unit 141 may be configured by a plurality of sensors. For example, the sensor unit 141 may be configured of a human sensor, a sound sensor, an illuminance sensor, and a temperature sensor.

  In the case of this configuration, the condition satisfaction determination unit 173 determines whether the detection result satisfies the predetermined condition independently for each sensor in steps SA3 and SA7. Then, the condition satisfaction determination unit 173 switches the operation state of the projector 100 when the detection result of any of the plurality of sensors satisfies the predetermined condition. Thus, the control unit 170 can more appropriately switch the standby state according to a change in the environment in which the projector 100 is installed.

<Modification>
Next, a modification will be described.
FIG. 4 is a diagram showing the transition of the operation state of the projector 100 in the modification.

  As apparent from comparison between FIG. 4 and FIG. 2, in the modification, it is possible to shift from the normal standby state 100C to the lighting state 100A.

  As illustrated in FIG. 3, when the operation state of the projector 100 is in the normal standby state 100C, as illustrated in FIG. 3, when the fifth transition trigger instructing transition to the lighting state 100A occurs, the control unit 170 lights from the normal standby state 100C. The state is shifted to the state 100A (step ST5). When shifting from the normal standby state 100C to the lighting state 100A, the power supply control unit 172 controls the power supply unit 201 to supply power to the light source drive unit 121, and the state transition control unit 174 controls the light source drive unit 121. Under control, the light source driving unit 121 supplies power to the light source 111 to turn on the light source 111. As the fifth transition trigger, the operation unit receives an operation instructing the lighting of the light source 111 by the operation of the remote control 5 or the operation panel 131 by the user, or the image input I / F unit 151 receives image data from the outside Can be mentioned.

  As shown in FIG. 4, by enabling the transition from the normal standby state 100C to the lighting state 100A, the following effects can be obtained. In FIG. 2, when transitioning from the normal standby state 100C to the lighting state 100A, the operation state of the projector 100 needs to be via the high-speed start standby state 100B. As described above, the transition from the normal standby state 100C to the high-speed start standby state 100B is triggered by the detection result of the sensor unit 141 satisfying a predetermined condition. Therefore, when the sensor unit 141 can not detect the sensor unit 141 for some reason, the projector 100 can not shift the operating state from the normal standby state 100C to the lighting state 100A, and the light source 111 can not be lit. Therefore, as shown in FIG. 4, by allowing transition from the normal standby state 100C to the lighting state 100A, the control unit 170 sets the operating state of the projector 100 even when the sensor unit 141 can not detect it for some reason. The normal standby state 100C can shift to the lighting state 100A, and the light source 111 can be lit.

  As described above, the projector 100 (display device) includes the light source unit 190. The projector 100 also includes a control unit 170 that controls the light source unit 190, and a sensor unit 141 (detection unit) that detects an environment in which the projector 100 is installed. The control unit 170 causes the light source unit 190 to emit light in the lighting state 100A (normal operation state), the power consumption of the light source unit 190 is smaller than the lighting state 100A in the high-speed start standby state 100B (first standby state), It can be executed by switching the normal standby state 100C (second standby state) in which the power consumption is smaller than the lighting state 100A and the high speed start standby state 100B. The control unit 170 shifts from the normal standby state 100C to the high-speed start standby state 100B, triggered by the detection result of the sensor unit 141 satisfying a predetermined condition.

  According to this configuration, the control unit 170 transitions from the normal standby state 100C to the high-speed start standby state 100B when the detection result of the sensor unit 141 satisfies the predetermined condition. It is possible to switch the standby state appropriately according to. More specifically, the control unit 170 can appropriately switch the standby state according to the presence or absence of the user around the projector 100.

  The high-speed start-up standby state 100B is a state in which the light source unit 190 can emit light in a shorter time than the normal standby state 100C.

  According to this configuration, since the light source unit 190 can emit light in a shorter time than the normal standby state 100C in the high-speed start-up standby state 100B, the projector 100 can be operated according to the environment in which the projector 100 is installed. The operating state can be promptly switched to the standby state in which the light source unit 190 can emit light. More specifically, the control unit 170 can quickly switch the operation state of the projector 100 to the standby state in which the light source unit 190 can emit light according to the presence or absence of the user around the projector 100.

  In addition, the projector 100 includes an operation unit (including an operation panel 131, a remote control light receiving unit 133, and an input / output I / F unit 135) that receives an operation of a user. The control unit 170 shifts to the lighting state 100A based on the operation received by the operation unit.

  According to this configuration, the control unit 170 can shift to the high-speed start standby state 100B according to the environment in which the projector 100 is installed, so that the light source unit 190 can be made to emit light promptly after receiving user's operation. it can.

  In addition, the control unit 170 shifts from the high-speed start standby state 100B to the normal standby state 100C when the detection result of the sensor unit 141 satisfies a predetermined condition.

  According to this configuration, the control unit 170 transitions from the high-speed start standby state 100B to the normal standby state 100C in response to the detection result of the sensor unit 141 satisfying the predetermined condition. Power consumption can be reduced appropriately. More specifically, when there is no user around the projector 100, the control unit 170 can suppress unnecessary power consumption.

  The sensor unit 141 is configured by at least one of a human sensor (sensor), a sound sensor (sensor), a temperature sensor (sensor), and an illuminance sensor (sensor).

  According to this configuration, the control unit 170 appropriately switches the standby state according to the environment in which the projector 100 is installed by detecting at least one of sound, presence / absence of a person, temperature, and illuminance. Can.

  Further, the sensor unit 141 is configured by a plurality of sensors. The control unit 170 shifts from the normal standby state 100C to the high speed startup standby state 100B based on the detection result of any of the plurality of sensors.

  According to this configuration, the control unit 170 shifts from the normal standby state 100C to the high-speed start standby state 100B based on the detection result of any of the plurality of sensors, so more depending on the environment in which the projector 100 is installed. It is possible to switch the standby state appropriately.

  The above-mentioned embodiment and modification are preferred embodiments of the present invention. However, the present invention is not limited to this, and various modifications can be made without departing from the scope of the present invention.

  For example, in the embodiment described above, a laser light source is illustrated as the light source 111, but the light source 111 is not limited to a laser light source, and may be a xenon lamp, an ultrahigh pressure mercury lamp, or an LED (Light Emitting Diode).

  Further, for example, in the above-described embodiment, the projector 100 is a liquid crystal projector using a transmissive liquid crystal panel, but may be a projector using a reflective liquid crystal panel or a digital mirror device. .

  Further, for example, in a case where the above-described control method (control method of the display device) of the projector 100 is realized by using a computer included in the projector 100 or an external device connected to the projector 100, the present invention It is also possible to configure in the form of a program executed by a computer to realize the above, a recording medium in which the program is recorded in a computer-readable manner, or a transmission medium for transmitting the program. As the recording medium, a magnetic or optical recording medium or a semiconductor memory device can be used. Specifically, flexible disks, HDDs (Hard Disk Drives), CD-ROMs (Compact Disk Read Only Memories), DVDs (Digital Versatile Disks), Blu-ray (registered trademark) Disc, magneto-optical disks, flash memories, cards, etc. Examples include portable or fixed recording media such as molded recording media. Further, the recording medium may be a nonvolatile storage device such as a random access memory (RAM), a read only memory (ROM), or an HDD, which is an internal storage device provided in the projector 100 or an external device connected to the projector 100.

  Further, in order to make the processing of the control unit 170 of the projector 100 easy to understand, the processing unit of the flowchart shown in FIG. 3 is divided according to the main processing content. The present invention is not limited by the method and names of division of processing units shown in the flowchart of FIG. Further, the processing of the control unit 170 can be divided into more processing units according to the processing content, or can be divided such that one processing unit includes more processing. Further, the processing order of the above-described flowchart is not limited to the illustrated example.

  Further, each functional unit of the projector 100 illustrated in FIG. 1 indicates a functional configuration realized by cooperation of hardware and software, and a specific implementation form is not particularly limited. Therefore, hardware corresponding to each functional unit does not necessarily have to be mounted, and it is of course possible to realize a function of a plurality of functional units by one processor executing a program. Further, a part of the functions realized by software in the above embodiment may be realized by hardware, or a part of the functions realized by hardware may be realized by software.

  Further, the display device of the present invention is not limited to a projector that projects an image on the screen SC. For example, the display device may be a liquid crystal monitor or liquid crystal television that displays an image on a liquid crystal display panel, a monitor device or a television receiver that displays an image on a PDP (plasma display panel), an OLED (Organic light-emitting diode), or an OEL. Various display devices such as a monitor device that displays an image on an organic EL display panel called (Organic Electro-Luminescence) or a self-luminous display device such as a television receiver are also included in the display device of the present invention.

  100: Projector (display device), 100A: lighting state (normal operation state), 100B: high speed start standby state (first standby state), 100C: normal standby state (second standby state) 110: projection unit, 111: Light source 112 Light modulation device 113 Projection optical system 120 Drive unit 121 Light source drive unit 122 Light modulation device drive unit 123 Projection optical system drive unit 131 Operation panel (operation unit) 133 remote control light receiver (operation unit) 135 input / output I / F unit (operation unit) 140 imaging unit 141 sensor unit (detection unit) 145 communication I / F unit 151 image input I / F unit 153: frame memory 155: image processing unit 160: storage unit 170: control unit 171: projection control unit 172: power supply control unit 173: condition satisfaction determination unit 1 4 ... the state transition control unit, 180 ... bus, 190 ... light source section, 200 ... power supply unit, 201 ... power supply unit, DG ... commercial AC power source, SC ... screen.

Claims (7)

It is a display apparatus provided with a light source part, and
A control unit that controls the light source unit;
A detection unit that detects an environment in which the display device is installed;
The control unit
The normal operation state in which the light source unit emits light, the first standby state in which the power consumption of the light source unit is smaller than the normal operation state, and the power consumption of the light source unit is smaller than the normal operation state and the first standby state 2 can be executed by switching the standby state,
The transition from the second standby state to the first standby state is triggered by the detection result of the detection unit satisfying a predetermined condition.
Display device. The first standby state is a state in which the light source unit can emit light in a shorter time than the second standby state.
The display device according to claim 1. It has an operation unit that accepts user operations,
The control unit transitions to the normal operation state based on an operation received by the operation unit.
The display device according to claim 1. The control unit
The transition from the first standby state to the second standby state is triggered by the detection result of the detection unit satisfying a predetermined condition.
The display device according to any one of claims 1 to 3. The detection unit is configured by at least one of a human sensor, a sound sensor, a temperature sensor, and an illuminance sensor.
The display device according to any one of claims 1 to 4. The detection unit is configured of a plurality of sensors.
The control unit shifts from the second standby state to the first standby state based on a detection result of any of a plurality of sensors.
The display device according to any one of claims 1 to 5. A control method of a display device, comprising: a light source unit; and a control unit that controls the light source unit,
The control unit is configured to cause the light source unit to emit light, a first standby state in which the power consumption of the light source unit is smaller than the normal operation state, and the power consumption of the light source unit is the normal operation state and the first It can be executed by switching the second standby state smaller than the standby state,
Detect the environment in which the display device is installed;
The transition from the second standby state to the first standby state is triggered by the detection result satisfying a predetermined condition.
Display control method.

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