JP6806220B2 - Electronic devices and control methods for electronic devices - Google Patents

Description

The present invention relates to an electronic device and a method for controlling the electronic device.

Conventionally, electronic devices used for adding information such as figures and characters to an image projected by a projector have been known. This type of electronic device is provided with a pen-shaped light emitting element that is held by the user during use, a light emitting element that emits light rays, and a sensor that outputs information indicating whether or not the tip of the pen is in contact with the writing surface. (See, for example, Patent Document 1).

International Publication No. 2013/114453

By the way, for the purpose of power saving of electronic devices, it is possible to provide a power saving mode in which power consumption is lower than that of the normal operation mode, and to control the operation mode to be switched according to the detection result of the sensor that detects holding by the user. Conceivable.
However, if a situation occurs in which reliable sensing cannot be performed due to a decrease in the sensitivity of the sensor or the like, the operation mode may not be switched from the power saving mode to the normal operation mode. For example, when the electrostatic sensor is used to detect whether or not the user holds the glove, if the user wears gloves, it may not be possible to detect that the user holds the glove. In this case, it is not possible to immediately switch to the normal operation mode, and the usability is impaired.

Therefore, an object of the present invention is to make it easier to improve usability and save power.

In order to achieve the above object, the present invention comprises an electronic device having a main body portion held by a user, a first detection unit for detecting that the main body portion is held, and an operation unit for receiving an operation. The second detection unit that detects that the operation unit has been operated, the first operation mode that operates the operation mode of the electronic device in an operation state suitable for use, and the power consumption more than the first operation mode. It is possible to switch to the second operation mode in which the above is suppressed, and the control unit that switches the operation mode based on the detection result of the first detection unit and the detection result of the second detection unit is provided. It is a feature.
According to the present invention, even when the first detection unit that detects that the main body is held cannot detect the holding of the main body due to a decrease in sensitivity or a change in the usage environment, the operation unit is operated. The operation mode can be switched by using the detection result of the second detection unit that detects the fact. Therefore, it is possible to save power while improving usability.

Further, according to the present invention, in the above configuration, the control unit detects that the main body unit is held by the first detection unit in the second operation mode, and the operation by the second detection unit. When it is detected that the unit has been operated, the mode is switched to the first operation mode.
According to the present invention, the electronic device can be switched to the first operation mode suitable for use when the main body portion is held and when the operation portion is operated.

Further, in the present invention, in the above configuration, the control unit does not detect that the main body unit is held by the first detection unit in the first operation mode, and the second detection unit does not detect that the main body unit is held. The second operation mode is switched to the second operation mode when a predetermined time elapses without detecting that the operation unit has been operated.
According to the present invention, it is possible to switch to the second operation mode when a predetermined time elapses in a state where the main body unit is not held and the operation unit is not operated, that is, in a state where the user does not use the operation unit. As a result, power saving can be achieved.

Further, in the present invention, in the above configuration, when the control unit detects that the main body unit is held by the first detection unit, the predetermined time is set to the first time, and the first detection is performed. When the unit does not detect that the main body is held and the second detection unit detects that the operation unit is operated, the predetermined time is set to a second time longer than the first time. It is characterized by setting the time.
In a configuration that assumes that the operation of the operation unit is performed while holding the main body unit, if the operation of the operation unit is detected but the holding of the main body unit is not detected, the first detection unit Is assumed to be the situation where the holding of the main body cannot be detected. Under such a situation, simply holding the main body unit does not switch from the second operation mode to the first operation mode, and it is necessary to operate the operation unit in order to switch to the first operation mode.
According to the present invention, when the operation of the operation unit is detected without detecting the holding of the main body, it takes longer time to switch to the second operation mode than when the holding of the main body is detected. Therefore, it is possible to prevent frequent switching to the second operation mode even though the main body is held.

Further, the present invention is characterized in that, in the above configuration, the first detection unit has a distortion sensor that detects the distortion of the main body unit.
According to the present invention, a distortion sensor that detects distortion of the main body can detect with high accuracy whether or not the main body is gripped by the user.

Further, the present invention is characterized in that, in the above configuration, the first detection unit includes an acceleration sensor that detects the acceleration of the main body unit.
According to the present invention, the acceleration sensor can detect the acceleration generated by the movement of the user holding the main body, and can detect with high accuracy whether or not the main body is held by the user.

Further, the present invention is characterized in that, in the above configuration, the first detection unit includes an electrostatic sensor that detects a change in capacitance.
According to the present invention, it is possible to detect with high accuracy whether or not the main body is held by the user by the electrostatic sensor that detects the change in capacitance.

Further, in the above configuration, the present invention includes a transmission unit that transmits a wireless signal to an external device, and when the control unit switches the operation mode to the first operation mode, the transmission unit performs the wireless signal. Is characterized by being able to transmit.
According to the present invention, a wireless signal can be transmitted to an external device in the case of the first operation mode.

Further, the present invention is a method for controlling an electronic device having a main body portion held by a user, and the operation mode of the electronic device is a first operation mode that operates in an operation state suitable for use, and the first operation mode. Controls to switch to the second operation mode, which consumes less power than the operation mode, and detects the detection result of the first detection unit that detects that the main body is held and the operation of the operation unit. The operation mode is switched based on the detection result of the second detection unit.
According to the present invention, even when the first detection unit that detects that the main body is held cannot detect the holding of the main body due to a decrease in sensitivity or a change in the usage environment, the operation unit is operated. The operation mode can be switched by using the detection result of the second detection unit that detects the fact. Therefore, it is possible to save power while improving usability.

The figure which shows the structure of the projection system which can use the indicator body which concerns on embodiment of this invention. A functional block diagram showing the projector along with its peripheral configuration. External view of the indicator. Functional block diagram of the indicator. A flowchart showing the operation of mode switching control. FIG. 5 is a continuation flowchart of FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram showing a configuration of a projection system 1 in which an indicator 70 according to an embodiment of the present invention can be used.
The projection system 1 includes a projector 10 that projects an image on a screen SC (projection surface). The projector 10 is installed directly above or diagonally above the screen SC, and projects an image toward the screen SC diagonally below. The screen SC is a flat plate or a curtain fixed to a wall surface or erected on a floor surface. The present invention is not limited to this example, and the wall surface can be used as a screen SC. In this case, the projector 10 may be mounted on the upper part of the wall surface used as the screen SC.

The projector 10 is connected to an external image supply device such as a PC (personal computer), a video playback device, or a DVD playback device, and an image is displayed on the screen SC based on the analog image signal or digital image data supplied from the image supply device. To project. Further, the projector 10 may be configured to read image data stored in the built-in storage unit 35 (FIG. 2) or an externally connected storage medium and display the image on the screen SC based on the image data.

The indicator body 70 is a user operation device in which the user performs an instruction operation on the screen SC. The indicator 70 is an electronic device incorporating an electronic component such as a light emitting unit 86 (FIG. 4), and the projector 10 detects a user-instructed position by detecting light from the light emitting unit 86. be able to. The indicator 70 will be described later.

The projection system 1 functions as an interactive whiteboard system, detects an instruction operation performed by the user by the instruction body 70, and performs a process of reflecting the instruction position on the projected image.
Specifically, the projection system 1 has a process of drawing a figure or arranging a character or a symbol at a designated position, a process of drawing a figure along a locus of the designated position, and a drawn figure or a placed character. Alternatively, the process of erasing the symbol is performed. Further, the figures drawn on the screen SC, the arranged characters or symbols can be saved as image data, and can be output to an external device.
Further, the projection system 1 may use the indicator 70 as a pointing device, detect the indicated position of the indicator 70 in the image projection region where the projector 10 projects an image on the screen SC, and output the coordinates thereof. Further, a GUI (Graphical User Interface) operation may be performed using these coordinates.

FIG. 2 is a functional block diagram showing the projector 10 together with the peripheral configuration.
The projector 10 includes an I / F (interface) unit 11 and an image I / F (interface) unit 12 as an interface connected to an external device. The I / F unit 11 and the image I / F unit 12 include a connector for wired connection, and may include an interface circuit corresponding to the connector. Further, the I / F unit 11 and the image I / F unit 12 may include a wireless communication interface. For example, the connector for wired connection and the interface circuit are compliant with wired LAN, IEEE1394, USB, and the like. Further, the wireless communication interface conforms to, for example, a wireless LAN, Bluetooth (registered trademark), or the like. An interface for image data such as HDMI (registered trademark), DisplayPort (trademark), and CoaXPless (trademark) can also be used for the image I / F unit 12. The image I / F unit 12 may include an interface for inputting audio data.

The I / F unit 11 is an interface for transmitting and receiving various data to and from an external device such as a PC. The I / F unit 11 inputs / outputs control data related to image projection, data for setting the operation of the projector 10, coordinate data of a designated position detected by the projector 10, and the like. The control unit 30 of the projector 10 has a function of transmitting and receiving data to and from an external device via the I / F unit 11.
The image I / F unit 12 is an interface for inputting digital image data. The projector 10 of the present embodiment projects an image based on digital image data input via the image I / F unit 12. The projector 10 may have a function of projecting an image based on an analog image signal. In this case, the image I / F unit 12 may include an analog image interface and an A / D conversion circuit that converts an analog image signal into digital image data.

The projector 10 includes a projection unit 20 that forms an optical image. The projection unit 20 includes a light source unit 21, an optical modulation device 22, and a projection optical system 23. The light source unit 21 includes a discharge tube light source such as a xenon lamp or an ultra-high pressure mercury lamp, or a solid-state light source such as an LED (Light Emitting Diode) or a laser light source. The light source unit 21 may include a reflector and an auxiliary reflector that guide the light emitted by the light source to the light modulation device 22. Further, the light source unit 21 is a lens group for enhancing the optical characteristics of the projected light, a polarizing plate, or a dimming element for reducing the amount of light emitted by the light source on the path leading to the light modulator 22 (all of which are shown in the figure). Omitted) may be provided.

The light modulation device 22 modulates the light emitted by the light source unit 21 to generate image light, and outputs the image light to the projection optical system 23. The optical modulation device 22 is composed of, for example, three transmissive liquid crystal panels corresponding to the three primary colors of RGB or three reflective liquid crystal panels. In this case, the light emitted by the light source unit 21 is separated into three colored colors of RGB and incident on the corresponding liquid crystal panel. An image is drawn on each of the three liquid crystal panels by the optical modulator driving unit 46, and image light is generated by these liquid crystal panels. The image light modulated by each liquid crystal panel is synthesized by a synthetic optical system such as a cross dichroic prism and emitted to the projection optical system 23.

Further, the optical modulation device 22 may be configured to modulate the light emitted by the light source unit 21 by a DMD (Digital Mirror Device). For example, the optical modulator 22 transmits light to a color wheel having a color filter that converts the light emitted by the light source unit 21 into light of the three primary colors of RGB, a DMD that modulates the light transmitted through the color wheel, and the color wheel and the DMD. It is equipped with a guiding optical system. The light modulator drive unit 46 draws an image on the DMD in synchronization with the rotation of the color wheel. The light emitted by the light source unit 21 passes through the color wheel to become the primary color light, which is modulated by the DMD and guided to the projection optical system 23.

The projection optical system 23 includes a lens group that guides the image light modulated by the light modulation device 22 toward the screen SC and forms an image on the screen SC. Further, the projection optical system 23 may include a zoom mechanism for enlarging / reducing the projected image of the screen SC and adjusting the focus, and a focus adjusting mechanism for adjusting the focus. When the projector 10 is a short focus type, the projection optical system 23 may be provided with a concave mirror that reflects image light toward the screen SC.

The projection unit 20 is connected to a light source drive unit 45 that lights the light source unit 21 under the control of the control unit 30 and a light modulation device drive unit 46 that operates the light modulation device 22 under the control of the control unit 30. The light source driving unit 45 may have a function of switching on / off of the light source unit 21 and adjusting the amount of light of the light source unit 21.

The projector 10 includes an image processing system that processes an image projected by the projection unit 20. This image processing system includes a control unit 30, a storage unit 35, an operation detection unit 17, an image processing unit 40, a light source drive unit 45, and an optical modulation device drive unit 46 that control the projector 10. Further, a frame memory 44 is connected to the image processing unit 40, and a position detection unit 50 is connected to the control unit 30. Each of these parts may be included in the image processing system.

The control unit 30 controls each unit of the projector 10 by executing a predetermined control program 36. The storage unit 35 non-volatilely stores the control program 36 executed by the control unit 30 and the data processed by the control unit 30. The storage unit 35 stores the setting screen data 37 of the screen for setting the operation of the projector 10, the setting data 38 indicating the contents set by using the setting screen data 37, and the like.

The image processing unit 40 processes the image data input via the image I / F unit 12 under the control of the control unit 30, and outputs the image signal to the optical modulation device driving unit 46. The processing executed by the image processing unit 40 includes discrimination processing between a 3D (stereoscopic) image and a 2D (plane) image, resolution conversion processing, frame rate conversion processing, distortion correction processing, digital zoom processing, color tone correction processing, brightness correction processing, and the like. Is. The image processing unit 40 executes the processing designated by the control unit 30, and if necessary, performs the processing using the parameters input from the control unit 30. Of course, it is also possible to execute a plurality of the above processes in combination.
The image processing unit 40 expands the image data input from the image I / F 12 into the frame memory 44, and executes the above-mentioned various processes on the expanded image data. The image processing unit 40 reads the processed image data from the frame memory 44, generates R, G, and B image signals corresponding to the image data, and outputs the processed image data to the optical modulation device driving unit 46.
The optical modulation device drive unit 46 is connected to the liquid crystal panel of the optical modulation device 22. The light modulation device driving unit 46 drives the liquid crystal panels based on the image signal input from the image processing unit 40, and draws an image on each liquid crystal panel.

The operation detection unit 17 is connected to the remote control light receiving unit 18 and the operation panel 19 that function as input devices, and detects an operation via the remote control light receiving unit 18 and the operation panel 19.
The remote control light receiving unit 18 receives an infrared signal transmitted by a remote controller (so-called remote controller) (not shown) used by the user of the projector 10 in response to a user operation. The remote control light receiving unit 18 decodes the infrared signal received from the remote controller, generates operation data indicating the operation content of the remote controller, and outputs the operation data to the control unit 30.
The operation panel 19 is provided on the outer housing of the projector 10 and has various switches. The operation detection unit 17 detects the operation of various switches and outputs an operation signal for the operated switch to the control unit 30.

The position detection unit 50 functions as an operation detection means for detecting an operation by the indicator 70. The position detection unit 50 includes an image pickup unit 51, a transmission unit 52, a shooting control unit 53, an indicator detection unit 54, and a coordinate calculation unit 55.
The image pickup unit 51 has an image pickup optical system, an image pickup element, an interface circuit, and the like, and photographs the projection direction of the projection optical system 23. The imaging optical system of the imaging unit 51 is arranged so as to face the same direction as the projection optical system 23, and has an angle of view that covers the range in which the projection optical system 23 projects an image on the screen SC. The image sensor is a CCD, CMOS, or the like capable of receiving the light (infrared light in this embodiment) emitted by the indicator 70. The image sensor 51 may include a filter that blocks a part of the light incident on the image sensor. For example, when receiving infrared light, a filter that mainly transmits light in the infrared region is placed in front of the image sensor. It may be arranged in. Further, the interface circuit of the image pickup unit 51 reads out the detection value of the image pickup element and outputs it.

The shooting control unit 53 causes the imaging unit 51 to perform shooting to generate captured image data. When the image sensor takes a picture with visible light, the image projected on the screen SC is taken. This captured image is used, for example, in a distortion correction process for correcting trapezoidal distortion or pincushion distortion of a projected image. Further, the photographing control unit 53 can photograph infrared light by the imaging unit 51, and the light emitted by the indicator 70 (infrared light in the present embodiment) is captured in the captured image in this case.

The indicator detection unit 54 detects the indicated position of the indicator 70 based on the captured image data captured by the imaging control unit 53. The indicator detection unit 54 detects an image of the light emitted by the indicator 70 from the captured image data when the imaging control unit 53 executes imaging by the imaging unit 51.
The coordinate calculation unit 55 calculates the coordinates of the designated position of the indicator 70 in the captured image data based on the position of the image detected by the indicator detection unit 54, and outputs the coordinates to the control unit 30. The coordinate calculation unit 55 converts the calculated coordinates in the captured image data into the coordinates in the image data drawn by the image processing unit 40 in the frame memory 44 and the coordinates in the input image data of the image I / F unit 12. You may output it.

The transmission unit 52 transmits an infrared signal (radio signal) to the indicator body 70 under the control of the indicator body detection unit 54. The transmission unit 52 has a light source such as an infrared LED, and turns this light source on and off according to the control of the indicator detection unit 54.

Next, the indicator 70 will be described.
FIG. 3 is an external view of the indicator body 70, and FIG. 4 is a functional block diagram of the indicator body 70. The indicator body 70 is formed in a pen shape that can be held and used by the user, that is, as shown in FIG. 3, a rod-shaped main body 71 held by the user and a taper provided at one end of the main body 71. The shape is formed so as to integrally include the tip portion 72 of the shape.
The indicator 70 includes a first sensor 81 (FIG. 4) that detects deformation of the main body 71 due to an external force. Further, the indicator body 70 includes a first operation switch 82 and a second operation switch 83 that function as operation units operated by the user.
The first sensor 81 is composed of a distortion sensor, and detects distortion that occurs when the user performs an operation of holding the main body 71 (first action indicated by reference numeral F1 in FIG. 3). The operation of the user holding the main body 71 includes an action of the user holding (or holding) the main body 71 like a pen.
As a result, the first sensor 81 functions as a first detection unit that detects that the main body unit 71 is held (including gripping) by the user.

The first operation switch 82 is a switch that operates by an operation of pressing the tip portion 72 against the screen SC or the like (second action indicated by reference numeral F2 in FIG. 3). In the present embodiment, the first operation switch 82 uses a push-type switch housed in the tip portion 72.
When the user specifies the position on the screen SC by using the indicator body 70, the user presses the tip portion 72 of the indicator body 70 against the screen SC. That is, the first operation switch 82 is an operation unit (first operation unit) that is operated when the user performs an instruction operation, in other words, an operation that is operated when the instruction body 70 is used as a pointing device. It is a department. The operation of the first operation switch 82 is detected by the detection circuit unit 85A of the indicator body 70. That is, the detection circuit unit 85A functions as a second detection unit that detects that the instruction is being operated.

The second operation switch 83 is an operation unit (second operation unit) that is operated when the user performs a predetermined operation other than the instruction operation. In the present embodiment, the second operation switch 83 uses a push-type switch provided on the side surface of the main body 71 so that the user can operate the indicator 70 while holding it (including the gripped state). Therefore, it is operated by a user pressing operation (third action indicated by reference numeral F3 in FIG. 3).
The operation of the second operation switch 83 is detected by the detection circuit unit 85A of the indicator body 70. That is, the detection circuit unit 85A also functions as a third detection unit that detects that a predetermined operation other than the instruction operation is being performed. The instruction assigned to the second operation switch 83 can be appropriately set.

The first sensor 81 may use another sensor within a range in which it can detect that the main body 71 is held. For example, the first sensor 81 may be a capacitance type touch sensor (so-called electrostatic sensor) that detects a change in capacitance. Further, the first sensor 81 may be an acceleration sensor, an angular velocity sensor, or a vibration sensor that detects acceleration, angular velocity, or vibration generated by the movement of the user while the main body 71 is held.
Further, the first operation switch 82 is not limited to the push-type switch, but is another switch or sensor (2nd action indicated by reference numeral F2 in FIG. 3) within a range in which the operation of pressing the tip portion 72 against the screen SC or the like can be detected. For example, an electrostatic sensor) may be applied.
Further, the second operation switch 83 is not limited to the push-type switch, and other switches or sensors (for example, electrostatic sensors) capable of detecting the user's operation may be applied.

As shown in FIG. 4, the indicator body 70 further includes an indicator body control unit 85, a light emitting unit 86, a light receiving unit 87, an indicator unit 88, a power supply control unit 89, and a battery 90.
The light emitting unit 86 has a light source that emits infrared light, and under the control of the indicator control unit 85, while the indicator 70 is operating in the normal operation mode described later, the light emitting unit 86 is infrared according to a predetermined light emission pattern. Light is emitted / stopped. The indicator body 70 emits light (radio signal) from the light emitting unit 86 from the tip portion 72, so that the indicator body detection unit 54 of the projector 10 detects the light emission pattern and the indicated position of the indicator body 70. The light emitting pattern is used for identifying the pressed state of the first operation switch 82 and the second operation switch 83. That is, the indicator control unit 85 causes the light emitting unit 86 to emit light in a different light emitting pattern depending on the pressed state of the first operation switch 82 and the second operation switch 83. Since infrared light is light outside the visible region, it is not visible to the user. However, it is not necessary to limit the light to infrared light.

The light receiving unit 87 receives the light (infrared light in this configuration) emitted from the transmitting unit 52 of the projector 10, and outputs a signal indicating the light receiving result to the indicator control unit 85. The indicator control unit 85 controls the light emission timing of the light emitting unit 86 based on the light receiving result, and synchronizes the light emission timing of the light emitting unit 86 with the detection timing by the indicator detection unit 54 of the projector 10.
The indicator unit 88 has a light source such as an LED provided on the main body 71 of the indicator body 70, and emits / stops visible light under the control of the indicator control unit 85. This visible light can be visually recognized from the outside through the window portion 71A provided in the main body portion 71. The indicator unit 88 emits light when, for example, the light emitting unit 86 is operating, or when the indicator 70 is in the normal operation mode, and can notify the user of predetermined information.

The power supply control unit 89 supplies the electric power of the battery 90 to each unit of the indicator body 70 under the control of the indicator body control unit 85. The battery 90 is a primary battery or a secondary battery. When the battery 90 is a secondary battery, the indicator 70 may be provided with a function of charging the battery 90 using external power (for example, power from a lamp line).

The indicator control unit 85 is composed of an arithmetic processing circuit such as a CPU and peripheral circuits thereof. The indicator control unit 85 centrally controls each portion of the indicator 70 and executes various arithmetic processes that realize a countdown timer function (timer function) and the like. Further, the indicator control unit 85 also controls to switch the operation mode of the indicator 70 between the normal operation mode and the power saving mode.
Here, the normal operation mode is an operation mode (first operation mode) that operates in an operation state suitable for use, and is an operation state in which power consumption is higher than that of the power saving mode.
Further, the power saving mode is an operation mode (second operation mode) in which power consumption is suppressed as compared with the first operation mode (including the normal operation mode) suitable for use. In the present embodiment, the power saving mode is an operation in which at least the first sensor 81, the first operation switch 82, and the like are detected and only the circuit unit having the timer function (detection circuit unit 85A in FIG. 4) is operated. It is in a state. The detection circuit unit 85A may be a packaged IC chip, or may be a plurality of unpackaged circuits.

More specifically, in the normal operation mode of the present embodiment, the indicator control unit 85 supplies operating power to each part of the indicator 70 by the power supply control unit 89, and all the functions of the indicator 70 can be used. To. As a result, the indicator control unit 85 operates with respect to the first sensor 81, the first operation switch 82, and the second operation switch 83. In addition, the indicator control unit 85 transmits an infrared signal (wireless signal) to the projector 10, which is an external device, by repeatedly causing the light emitting unit 86 to emit light in a predetermined light emitting pattern. Further, the indicator control unit 85 performs a process of synchronizing based on the light receiving result of the light receiving unit 87, a process of notifying the user by the indicator unit 88, a timer process, and the like.
The operations related to the first sensor 81, the first operation switch 82, and the second operation switch 83 are the first to first operations of the user based on the output signals of the first sensor 81, the first operation switch 82, and the second operation switch 83. 3 Actions This is an operation of detecting F1 to F3 and executing the corresponding process.

In the power saving mode, only the detection circuit unit 85A operates with the power of the battery 90. Therefore, the power consumption is lower than that in the normal operation mode. In this case, it is preferable to further reduce the power consumption by performing a process of lowering the operating voltage, a process of lowering the number of operating clocks, or the like. Further, the operation mode is not limited to the operation mode in which only the detection circuit unit 85A operates, and other parts may be operating as long as the power consumption is lower than that in the normal operation mode.

By the way, the first sensor 81 may not be able to detect the holding of the main body 71 due to a decrease in sensitivity or a change in the usage environment. If the configuration is such that the power saving mode is switched to the normal operation mode when the holding of the main body 71 is detected by the first sensor 81, it may not be possible to switch to the normal operation mode under such a situation.
Therefore, in the present embodiment, even if the first sensor 81 does not detect that the main body 71 is held, if it is detected that the first operation switch 82 has been operated, control for switching the operation mode (mode switching). Control) is performed.

Hereinafter, the operation of the mode switching control will be described with reference to the flowcharts of FIGS. 5 and 6. Note that FIG. 6 is a flowchart continuing from FIG. In FIGS. 5 and 6, the values T1 and T2 are the standby times until the transition to the power saving mode, and the second time T2 is a longer time than the first time T1 (T1 <T2). The values M and N are variables.
Here, in the power saving mode (“Sleep” in FIG. 5), only the detection circuit unit 85A of the indicator control unit 85 operates, so whether or not the indicator 70 is held by the first sensor 81 is determined. 1 Whether or not the operation switch 82 is operated is monitored.

As shown in FIGS. 5 and 6, when it is detected by the first sensor 81 that the indicator 70 is held by the first sensor 81 in the power saving mode (step S1; YES), the detection circuit unit 85A has a timer time T. Is set to the first time T1 (step S2). After that, the detection circuit unit 85A shifts to the normal operation mode.
After shifting to the normal operation mode, the indicator control unit 85 is in a state where the holding of the indicator 70 is not detected and the operation of the first operation switch 82 is not detected (steps S6; NO, S7; NO) for the first time. When T1 elapses (step S8; YES), the mode shifts to the power saving mode.

That is, after the user holds the indicator body 70, if the indicator body 70 is not released from the hand and no operation is performed, the power saving mode is switched to after the relatively short first time T1 has elapsed. As a result, if there is no action by the user (first and second actions F1 and F2 shown in FIG. 3) in the normal operation mode, the mode can be switched to the power saving mode in a short time, and power saving can be efficiently achieved. For example, by setting the first time T1 within a range of about several seconds, it is possible to switch from the normal operation mode to the power saving mode within a few seconds.

On the other hand, in the power saving mode, when it is not detected that the indicator 70 is held (step S1; NO) and it is detected that the first operation switch 82 is operated (step S3; YES), the detection circuit The unit 85A sets the timer time T to the second time T2 (step S4). After that, the detection circuit unit 85A shifts to the normal operation mode.
In a normal usage mode, it is difficult for the user to operate the first operation switch 82 without holding the indicator body 70. Therefore, it is detected that the first operation switch 82 is operated without detecting the holding of the indicator body 70. If this is the case, sensing by the first sensor 81 may not be possible due to a decrease in sensitivity or a change in the usage environment.

In the present embodiment, when it is detected that the first operation switch 82 is operated without detecting the holding of the indicator body 70 (step S1; NO, S3; YES), the indicator body control unit 85 operates normally. After the transition to the mode, when the second time T2 elapses (step S8; YES) in a state where neither the holding of the indicator 70 nor the operation of the first operation switch 82 is detected (step S6; NO, S7; NO), the power saving mode Move to.
As a result, even if the user has not been able to sense by the first sensor 81, if the indicator 70 is pressed against the screen SC before the second time T2 elapses, the user can continue the instruction operation by the indicator 70. it can. For example, by setting the second time T2 within the range of several tens of seconds to several minutes, the instruction operation by the indicator 70 can be continued during that period, so that the indicator 70 is held. It is possible to suppress the situation where the mode is frequently switched to the power saving mode. Therefore, the usability of the user can be improved. Further, when the second time T2 elapses, the mode shifts to the power saving mode, so that power saving can be achieved.

Further, in the power saving mode, when it is not detected that the indicator 70 is held (step S1; NO) and it is not detected that the first operation switch 82 is operated (step S3; NO), the detection circuit unit 85A shifts to the process of step S1. As a result, the power saving mode continues. That is, when the indicator 70 is not held and the first operation switch 82 is not operated, the power saving mode is continued and the power saving is achieved.

The operation when shifting to the normal operation mode will be described in detail. First, the indicator control unit 85 resets the variables M and N to the initial value of zero when the mode shifts to the normal operation mode. After that, the indicator control unit 85 resets the time counting (countdown) by the timer function, and starts the time counting of the timer time T set in the first time T1 or the second time T2 (step S5). When it is detected that the indicator 70 is held in the normal operation mode (step S6; YES), the indicator control unit 85 increments the value N by the value 1 and resets the value M to zero (step S6; YES). Step S11). Subsequently, the indicator control unit 85 determines whether or not the value N is 2 or more (step S12).
When the value N is not 2 or more (step S12; NO), the indicator control unit 85 shifts to the process of step S5. On the other hand, when the value N is 2 or more (step S12; YES), the indicator control unit 85 sets the timer time T to the first time T1 (step S13), and proceeds to the process of step S5.

That is, when the first sensor 81 detects that the indicator 70 is held twice in succession in the normal operation mode, the timer time T is set to the first time T1.
When it is detected twice in succession that the indicator 70 is held by the first sensor 81, it is considered that the sensing by the first sensor 81 is possible. Therefore, by setting the relatively short first time T1, the indicator 70 is not held (step S6; NO) and the first operation switch 82 is not operated only during the first time T1 (step). S7; NO), the power saving mode can be quickly switched.
In this way, when sensing by the first sensor 81 is possible, if there is no action by the user (first and second actions F1 and F2 shown in FIG. 3), the power saving mode is switched to in a short time, which hinders usability. It is possible to save power without doing so. Further, in the power saving mode, the user simply holds the indicator body 70 to switch to the normal operation mode, which is convenient.

On the other hand, in the normal operation mode, when it is detected that the first operation switch 82 is operated without detecting the holding of the indicator body 70 (step S6; NO, S7; YES), the indicator body control unit 85 The value M is incremented by the value 1 and the value N is reset to zero (step S14). Subsequently, the indicator control unit 85 determines whether or not the value M is 2 or more (step S15), and if it is not 2 or more (step S15; NO), proceeds to the process of step S5.
When the value M is 2 or more (step S15; YES), the indicator control unit 85 sets the timer time T to the second time T2 (step S16), and proceeds to the process of step S5.

As a result, when sensing by the first sensor 81 is not performed, if the operation of the first operation switch 82 is detected twice in succession, the standby time (second time T2) until the transition to the power saving mode is performed. Set long. Therefore, it is possible to suppress a situation in which the user frequently switches to the power saving mode even though he / she holds the indicator body 70. Further, if the user presses the indicator body 70 against the screen SC before the second time T2 elapses, the normal operation mode continues, and the instruction operation by the indicator body 70 can be continued.
On the other hand, if the user does not press the indicator 70 against the screen SC, the power saving mode is entered after the lapse of the second time T2. Therefore, both usability and power saving can be achieved at the same time. The above is the operation of mode switching control.

As described above, the indicator 70 according to the present embodiment indicates that the first sensor 81 (first detection unit) for detecting that the main body 71 is held and the first operation switch 82 have been operated. It includes a detection circuit unit 85A (second detection unit) for detection. Then, the indicator control unit 85 switches the operation mode based on the detection result of the first sensor 81 and the detection result of the first operation switch 82.
According to the configuration of the indicator body 70 and the control method of the indicator body 70, the detection result of the first operation switch 82 even if the sensing by the first sensor 81 is not possible due to a decrease in sensitivity or a change in the usage environment. The operation mode can be switched using. Therefore, it is possible to save power while improving usability.

Further, according to the above configuration and control method, in the case of the configuration in which the touch sensor (electrostatic sensor) is applied to the first sensor 81, the operation mode can be switched even if the user wears gloves.

Further, in the power saving mode, the indicator control unit 85 detects that the main body 71 is held by the first sensor 81 or that the first operation switch 82 is operated. In that case, switch to the normal operation mode. As a result, even when sensing by the first sensor 81 is not possible, the power saving mode can be switched to the normal operation mode by operating the first operation switch 82, and the user can use the indicator body 70.

Further, in the normal operation mode, the indicator control unit 85 does not detect that the main body 71 is held, and the operation of the first operation switch 82 is not detected, and the timer time T (first time). After T1 or the second time T2) has elapsed, the power saving mode is switched to. As a result, when not used by the user, the power saving mode can be switched to after the timer time T (predetermined time) has elapsed. Therefore, power saving can be achieved.

Further, when the indicator control unit 85 detects that the main body 71 is held, the timer time T is set to the first time T1, and the indicator control unit 85 does not detect that the main body 71 is held, and When it is detected that the first operation switch 82 has been operated, that is, when sensing by the first sensor 81 has not been performed, the timer time T is set to the second time T2, which is longer than the first time T1. As a result, it is possible to prevent the user from frequently entering the power saving mode even though the main body 71 is held. Therefore, it is advantageous for improving usability. The first time T1 and the second time T2 may be freely set by the user or the like.

Further, when the situation in which the operation of the first operation switch 82 is detected without detecting the holding of the main body 71 is continuously performed a plurality of times, the timer time T is set to the second time T2, and the holding of the main body 71 is performed. Since the timer time T is set to the first time T1 when the detected situations are consecutive a plurality of times, it is possible to prevent the timer time T from being switched even if each situation occurs accidentally only once. .. The number of times required to set the first time T1 or the second time T2 is not limited to two, and may be three or more. Alternatively, it may be set to once without being limited to a plurality of times.

Further, since the first sensor 81 is a distortion sensor that detects the distortion of the main body 71, it is possible to detect with high accuracy whether or not the main body 71 is held (including gripping) by the user.
Further, when an acceleration sensor for detecting the acceleration of the main body 71 is used for the first sensor 81, the acceleration sensor can detect the acceleration generated by the movement of the user holding the main body 71, and the user can detect the acceleration generated by the user. Whether or not the 71 is held (including gripping) can be detected with high accuracy.
Further, as the first sensor 81, an electrostatic sensor that detects a change in capacitance can also be used. When using the electrostatic sensor, if the user wears gloves, it becomes difficult to detect the holding of the main body 71, but the operation mode can be switched by operating the first operation switch 82. Is possible.
Further, the first sensor 81 may have a plurality of sensors such as the above-mentioned distortion sensor and acceleration sensor. This makes it easier to improve the detection accuracy of whether or not the main body 71 is held.

Further, the indicator 70 includes a light emitting unit 86 (transmitting unit) that transmits an infrared signal (wireless signal) to the projector 10 which is an external device, and when the operation mode is switched to the normal operation mode, the light emitting unit 86 Can transmit infrared signals. As a result, in the normal operation mode, an infrared signal is transmitted to the projector 10, and the position of the indicator 70 can be detected and identified.

The above-described embodiment shows a preferred embodiment of the present invention, does not limit the present invention, and various modifications can be carried out without departing from the gist of the present invention. For example, in the above embodiment, the configuration of the indicator 70 shown in FIG. 4 shows a functional configuration, and the specific mounting embodiment is not particularly limited. For example, in the above embodiment, the indicator control unit 85 of the indicator 70 includes a circuit unit (a part of the detection circuit unit 85A) that functions as a second detection unit that detects whether or not the instruction is being operated. As described above, this circuit unit may be separate from the indicator control unit 85.

In the above-described embodiment, the operation mode is switched based on the detection result of the first sensor 81 and the detection result of the first operation switch 82, and the time for switching from the normal operation mode to the power saving mode is changed. However, instead of the detection result of the first operation switch 82, it may be based on the detection result of the second operation switch 83, or based on the detection result of both the first operation switch 82 and the second operation switch 83. It may be. That is, in the power saving mode, when the operation of the first operation switch 82 or the second operation switch 83 is detected without detecting the holding of the main body 71, the timer time T is set to the second time T2 and the normal operation mode is performed. In the normal operation mode, the timer time T is set to the second time when the operation of the first operation switch 82 or the second operation switch 83 is detected twice in succession without detecting the holding of the main body 71. It may be set to T2.

Further, in the above embodiment, the case where the indicator 70 is a pen type is illustrated, but the shape and size of the indicator 70 are not particularly limited to the pen type. Further, some or all of the functions realized by hardware in the above embodiment may be realized by software.

Further, in the above embodiment, the case where the present invention is applied to the indicator 70 used in the projection system 1 has been described, but the present invention is not limited to this. In short, it has a main body 71 that is held by the user during use, and the operation modes are a first operation mode (not limited to the normal operation mode) suitable for use and a second operation mode that suppresses power consumption. The present invention can be widely applied to electronic devices that can be switched to a power saving mode.
Electronic devices other than the indicator body 70 are, for example, a remote controller held (including gripping) and used by the user, and a portable device such as a digital camera.

1 ... Projection system, 10 ... Projector, 70 ... Indicator (electronic device), 71 ... Main body, 72 ... Tip, 81 ... 1st sensor (1st detection), 82 ... 1st operation switch (operation) , 83 ... 2nd operation switch, 85 ... Indicator control unit (control unit), 85A ... Detection circuit unit (2nd detection unit), 86 ... Light emitting unit (transmitting unit), 87 ... Light receiving unit, 88 ... Indicator unit, 89 ... Power control unit, 90 ... Battery, SC ... Screen.

Claims (7)

An electronic device having a main body held by a user.
A distortion sensor that detects the distortion of the main body and
Switch and
A clock that measures the time since the main body is stationary and the time since the switch is operated.
With
The distortion in the first case where the main body is not distorted when the switch is operated, the switch is not operated thereafter, the main body is temporarily distorted, and then the distortion disappears. The time from the detection of is detected until the mode is switched is T1.
In the second case where the main body is not distorted when the switch is operated, the switch is not operated thereafter, and the main body is not distorted, the time from when the switch is operated until the mode is switched. Let T2
T1 <T2,
An electronic device characterized by that. An electronic device having a main body held by a user.
A motion sensor that detects the movement of the main body and
Switch and
A clock that measures the time since the main body is stationary and the time since the switch is operated.
With
The said in the first case where the main body is stationary when the switch is operated, the switch is not operated thereafter, the main body makes a predetermined movement, and then the main body continues to be stationary. Let T1 be the time from the predetermined movement to the mode switching.
In the second case where the main body is stationary when the switch is operated, the switch is not operated thereafter, and the main body continues to be stationary, from the operation of the switch to the switching of the mode. If the time is T2
T1 <T2,
An electronic device characterized by that. T1 is the time from the predetermined movement in the first case to the mode switching in which the power consumption is reduced.
2. The electronic device according to claim 2 . T2 is the time from the operation of the switch in the second case to the mode switching in which the power consumption is reduced.
The electronic device according to any one of claims 1 to 3. The electronic device according to any one of claims 1 to 4, wherein it is determined that the position has been specified by the user when the switch is operated. The electronic device according to any one of claims 1 to 5, further comprising a light emitting unit that emits infrared light. The electronic device according to any one of claims 1 to 6, further comprising a secondary battery for supplying electric power to each part of the main body.

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