JP2019152478A - Video display device and video display method - Google Patents

Abstract

To provide a video display device and a video display method with which it is possible to detect the presence of a user with high accuracy while shortening a period as much as possible for which the user is irradiated with an infrared ray and placed in an uncomfortable state, irrespective of whether the device is in a power-save mode or a normal mode.SOLUTION: The video display device comprises: a passive type human sensor for detecting prescribed light radiated from a human body without irradiation with the prescribed light and thereby detecting the presence of a human body and outputting a detection result; an active type human sensor for irradiation with prescribed light and detecting the prescribed light reflected from a human body and thereby detecting the presence of a human body and outputting a detection result; and a control unit for determining whether or not the active type human sensor outputs the same detection result as the detection result of the passive type human sensor, and causing the power state of the video display device to transition between a normal mode and a power-save mode.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a video display device and a video display method.

  Video display devices that display various types of information such as images are used in various computer terminals and various electronic devices such as personal computers and workstations. In such a video display device, if no operation is performed during a preset standby time, the power source of the video display device is shifted to the power saving mode or the power source is turned on to save power. Cutting is done.

  However, even if the user is in front of the computer terminal, since the operation is not performed for a predetermined time or more, if the video display device is turned off after a certain waiting time, it may be inconvenient for the user.

  Therefore, in Patent Document 1, an infrared sensor is installed on the outer periphery of the display surface of the video display device, and it is detected by this infrared sensor whether or not there is a user facing the video display device. In the case of detecting, a control means is proposed for preventing the video display device from being switched to the power saving mode or being turned off.

For the following explanation, a human sensor that emits infrared light from itself and detects the reflected wave of the emitted infrared light is called an active human sensor, and does not emit infrared light from itself but emits infrared light from an object. A human sensor that only detects the sensor is called a passive human sensor.
The active human sensor includes a light emitting unit that emits infrared rays and a light receiving unit that detects infrared rays. By observing the reflected infrared reflected wave, the presence or absence of an object present in front of the sensor is detected.

On the other hand, the passive human sensor has a light receiving unit that does not irradiate infrared rays from itself and detects a minute amount of infrared rays emitted from the surface of the object.
The light receiving unit reads the infrared energy difference between the background and the object, and detects the presence or absence of the object existing in front of the sensor.
Infrared detection sensitivity is high in principle, but it is easily affected by noise, such as the influence of environmental temperature and convection of air conditioning, and the change of the power supply load state of the device itself as in Patent Document 2, and a slight change in infrared rays. May be observed as a change in seating status.
From these points, the detection accuracy of the passive human sensor is inferior to that of the active human sensor for the purpose of detecting the human body sitting in front of the video display device.

JP-A-4-280311 Japanese Patent No. 6156951

  However, in a video display device that is equipped with a human sensor and has the function of detecting the human body by detecting the reflected infrared wave emitted from the human sensor, the video display device is installed in front of the user, such as an office desk. In the case of being used, the infrared light emitted from the human sensor feels annoying for the user and cannot concentrate on the desk work.

  In addition, for the above-mentioned countermeasures, that is, for the countermeasures to prevent the user from feeling obstructive to the infrared light emitted from the human sensor, for example, the position of the infrared irradiation is displayed as an image. When installed in a position other than directly in front of the apparatus, it becomes difficult for the user to recognize the irradiation of infrared rays, but the accuracy of detecting the user's seating state by the human sensor is deteriorated.

  The present invention can solve the above problem, that is, whether it is in a power saving state or a normal state, while irradiating the user with infrared rays and reducing the period of uncomfortable state as much as possible, And it aims at providing the video display apparatus and video display method which can detect the presence or absence of a user with high precision.

  In order to solve the above problems, according to one embodiment of the present invention, the presence or absence of a human body is detected by detecting the predetermined light emitted from the human body without irradiating the predetermined light, and the detection result is output. A passive human sensor, an active human sensor that detects the presence of a human body by detecting the predetermined light reflected from the human body by irradiating the predetermined light, and outputs a detection result; It is determined whether the active human sensor outputs the same detection result as the detection result of the passive human sensor, and based on the determination result, the power state of the video display device is set to a normal state and a power saving state. And a control unit that executes state transition between the video display device and the video display device.

  Further, according to one embodiment of the present invention, a passive human sensor detects the presence or absence of a human body by detecting the predetermined light emitted from the human body without irradiating the predetermined light, and detects the detection result. The passive human sensing process for outputting and the active human sensor detects the presence of the human body by detecting the predetermined light reflected from the human body by irradiating the predetermined light, and the detection result And an active human sensing process for outputting a signal, and a control unit determines whether the active human sensor outputs the same detection result as the detection result of the passive human sensor, based on the determination result And a control step of executing a state transition between the normal state and the power saving state of the power state of the video display device.

According to one aspect of the present invention, the control unit determines whether or not the active human sensor outputs the same detection result as the detection result of the passive human sensor, and based on the determination result, the video display device The state transition is executed between the normal state and the power saving state.
This makes it possible to detect the presence or absence of the user with high accuracy while reducing the period during which the user is in an uncomfortable state by irradiating infrared rays regardless of whether the power saving state or the normal state. Therefore, it is possible to provide a video display device and a video display method that can perform the above-described functions.

It is a block diagram showing the structure of this invention apparatus. It is a figure showing the mode of the detection of the infrared rays by the passive type human sensitive sensor mounted in this invention apparatus. It is a figure showing the mode of irradiation and detection of infrared rays by an active human sensor mounted in the device of the present invention. It is a figure which shows the state transition of the electric power state of this invention apparatus. It is a flowchart of a human body detection process in case the electric power state of this invention apparatus is a normal state. It is a flowchart of a human body detection process in case the electric power state of this invention apparatus is a power saving state. It is a block diagram showing the basic composition of the device of the present invention.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a block diagram showing the configuration of the apparatus of the present invention.
As shown in FIG. 1, the video display device 100 includes an active human sensor 110, a passive human sensor 120, a control unit 130, a power supply 140, a video display unit 150, a scaling IC, a ROM 170, and a RAM 180. The
In FIG. 1, arrows indicate the directions of control and information input / output.

The video display device 100 is a video display device such as a liquid crystal display or a liquid crystal television.
As shown in FIG. 1, the video display device 100 is a video display device on which an active human sensor 110 and a passive human sensor 120 are mounted.
In addition, the video display device 100 includes the control unit 130, and the control unit 130 shifts the device from the normal power state to the power saving state based on the detection result of each human sensor, or vice versa. The entire video display apparatus 100 is controlled to perform the state transition.
In other words, the video display device 100 of the present invention device performs control so that the infrared irradiation from the active human sensor 110 (mounted human sensor) is always stopped and the infrared irradiation is performed only when necessary. Features. In addition to simply lowering the frequency of infrared irradiation, the high detection accuracy of the seating / seating state, which is a merit of the infrared irradiation type human sensor, is maintained.

FIG. 2 is a diagram showing the state of infrared detection by a passive human sensor mounted on the apparatus of the present invention.
The passive human sensor 120 is a sensor component having an infrared light receiving unit 221 composed of a photodiode or the like.
The passive human sensor 120 detects infrared rays emitted from the human body as shown in FIG.
The control unit 130 of the video display device 100 is connected to the passive human sensor 120 through internal wiring such as I2C (Inter-Integrated Circuit), and controls acquisition of detection results of the sensors and change of detection settings.

FIG. 3 is a diagram showing the state of irradiation and detection of infrared rays by an active human sensor mounted on the apparatus of the present invention.
The active human sensor 110 is a sensor component having an infrared light receiving unit 211 configured with a photodiode and an infrared light emitting unit 212 configured with an infrared light emitting diode.
As shown in FIG. 3, the active human sensor 110 irradiates infrared rays from itself, and detects the presence or absence of a human body by detecting the infrared rays of the reflected waves.
The control unit 130 of the video display device 100 is connected to the active human sensor 110 through internal wiring such as I2C, and controls acquisition of detection results of the sensor and change of detection / irradiation settings.

Returning to FIG. 1, the control unit 130 is a circuit including an MPU (Micro Processing Unit) in which control software of the video display device 100 is written. As described above, the control unit 130 controls the acquisition of the detection result of the passive human sensor 120 and the change of the detection setting, and controls the acquisition of the detection result of the active human sensor 110 and the change of the detection / irradiation setting. To do.
Further, the control unit 130 determines whether or not the active human sensor 110 outputs the same detection result as the detection result of the passive human sensor 120, and based on the determination result, the power state of the video display device 100 The state transition is executed between the normal state and the power saving state. Details will be described later.

The power source 140 is a built-in power source of the video display device 100 and generates power necessary for the operation of each part of the device.
The video display unit 150 is a video display component such as a liquid crystal panel or an organic EL (Electro Luminescence) panel.
The scaling IC 160 is an IC (Integrated Circuit) that performs various conversions such as enlargement / reduction and color correction on the video signal input to the video display device 100 and outputs the video signal to the video display unit 150.
A ROM (Read Only Memory) 170 is a nonvolatile memory capable of recording the measurement state of the human sensor and data.
A RAM (Random Access Memory) 180 is a temporary storage area for the control unit 130 to perform arithmetic processing.

FIG. 4 is a diagram showing the state transition of the power state of the device of the present invention.
The video display apparatus 100 changes the power state shown in FIG.
First, after the power supply 140 of the video display device 100 is turned on with a vacation switch, a push switch, or the like, the power OFF state is changed to the Power ON state and the normal state.
The normal state refers to a state in which the user uses the video display device 100. On the other hand, the power saving state refers to a state in which the video display device 100 is in a dormant state and consumes less power than the normal state. Even in the power saving state, the control of the human sensor (passive human sensor 120, active human sensor 110) by the control unit 130 is continued.
In the normal state, processing using the human sensor shown in the flow of FIG. 5 is performed, and when it is determined that the user of the apparatus is away, the power saving state is entered.
On the other hand, in the power saving state, the process using the human sensor shown in the flow of FIG. 6 is performed, and when it is determined that the user of the apparatus is seated, the process shifts to the normal state.
Next, processing using the human sensor shown in the flow of FIG. 5 and processing using the human sensor shown in the flow of FIG. 6 will be described.

FIG. 5 is a flowchart of human body detection processing when the power state of the device of the present invention is the normal state.
First, human body detection is performed by a passive human sensor (step S501).
Specifically, the passive human sensor 120 detects the presence of a human body by detecting infrared rays emitted from the human body, and outputs a detection result.
Subsequently, it is determined whether or not a human body has been detected (step S502).
Specifically, the control unit 130 determines whether a human body has been detected based on the detection result from the passive human sensor 120. When the human body can be detected (step S502—NO), the control unit 130 continues monitoring with the passive human sensor 120 (step S501). On the other hand, when the human body cannot be detected (step S502—YES), the control unit 130 proceeds to the process of step S504.

In the process of step S504, it is determined that there is a possibility of leaving the seat, and the human body is detected by the active human sensor (step S504).
Specifically, the control unit 130 confirms the reflection of infrared rays by irradiating infrared rays from the active human sensor 110.
Subsequently, it is determined whether or not a human body has been detected (step S505).
Specifically, the control unit 130 determines whether or not a human body has been detected based on the detection result from the active human sensor 110. When the human body can be detected (step S505—NO), the control unit 130 proceeds to the process of step S503. On the other hand, when the human body cannot be detected (step S505—YES), the control unit 130 proceeds to the process of step S506.
In the process of step S503, the operation of the active human sensor is stopped. (Step S503).
Specifically, the control unit 130 stops the operation of the active human sensor 110 based on the detection result from the active human sensor 110 and stops the infrared irradiation from the active human sensor 110.

On the other hand, in the process of step S506, the display device is shifted to the power saving state (step S506).
Specifically, the control unit 130 shifts the power state of the video display device 100 from the normal state to the power saving state.
Subsequently, the operation of the active human sensor is stopped. (Step S507).
Specifically, the control unit 130 stops the operation of the active human sensor 110 based on the detection result from the active human sensor 110 and stops the infrared irradiation from the active human sensor 110.
On the other hand, the detection (monitoring) of the human body by the passive human sensor is continued (step S508).
Specifically, the control unit 130 continues to acquire the detection result from the passive human sensor 120.

As described above, in the normal state of the power state, the control unit 130 determines that the user is not detected by the passive human sensor 120 (step S502—YES). The human body is detected as having the possibility of leaving (step S504). Then, the control unit 130 determines whether or not the active human sensor 110 outputs the same detection result as the determination result that the passive human sensor 120 could not detect a human body (YES in step S502). A determination is made as to whether or not the type human sensor 110 could not detect a human body) (step S505).
If the active human sensor 110 can detect the human body (step S505-NO), the active human is determined based on the determination result (that there is a user (with or without a user)). The operation of the sense sensor 110 is stopped (step S503).
As a result, it is possible to accurately detect that there is a user (the presence or absence of the user) while shortening the period during which the user is irradiated with infrared rays to make the user uncomfortable. .

In addition, in the normal state of the power state, the control unit 130, when the passive human sensor 120 cannot detect the human body (step S502-YES), the user is separated from the active human sensor 110. The human body is detected as a possibility of seating (step S504). Then, the control unit 130 determines whether or not the active human sensor 110 outputs the same detection result as the determination result that the passive human sensor 120 could not detect a human body (YES in step S502). A determination is made as to whether or not the type human sensor 110 could not detect a human body) (step S505).
If the active human sensor 110 cannot detect the human body (step S505—YES), the display device is based on the determination result (that there is a user (no user is present)). The (video display device 100) is shifted to the power saving state (step S506), and the operation of the active human sensor 110 is stopped (step S507).
Accordingly, it is possible to detect that there is no user (no user is present), and the display device (video display device 100) is shifted to the power saving state.

FIG. 6 is a flowchart of human body detection processing when the power state of the device of the present invention is the power saving state.
First, human body detection is performed using a passive human sensor (step S601).
Specifically, the passive human sensor 120 detects the presence of a human body by detecting infrared rays emitted from the human body, and outputs a detection result.
Subsequently, it is determined whether or not a human body has been detected (step S602).
Specifically, the control unit 130 determines whether a human body has been detected based on the detection result from the passive human sensor 120. When the human body cannot be detected (step S602-NO), the control unit 130 continues monitoring with the passive human sensor 120 (step S601). On the other hand, when the human body can be detected (step S602—YES), the control unit 130 proceeds to the process of step S604.

In the process of step S604, the human body is detected by the active human sensor as the possibility of sitting (step S604).
Specifically, the control unit 130 confirms the reflection of infrared rays by irradiating infrared rays from the active human sensor 110.
Subsequently, it is determined whether or not a human body has been detected (step S605).
Specifically, the control unit 130 determines whether or not a human body has been detected based on the detection result from the active human sensor 110. When the human body cannot be detected (step S605—NO), the control unit 130 proceeds to the process of step S603. On the other hand, when the human body can be detected (step S605—YES), the control unit 130 proceeds to the process of step S606.
In the process of step S603, the operation of the active human sensor is stopped. (Step S603).
Specifically, the control unit 130 stops the operation of the active human sensor 110 based on the detection result from the active human sensor 110 and stops the infrared irradiation from the active human sensor 110.

On the other hand, in the process of step S606, the display device is shifted to the normal state (step S606).
Specifically, the control unit 130 shifts the power state of the video display device 100 from the power saving state to the normal state.
Subsequently, the operation of the active human sensor is stopped. (Step S607).
Specifically, the control unit 130 stops the operation of the active human sensor 110 based on the detection result from the active human sensor 110 and stops the infrared irradiation from the active human sensor 110.
On the other hand, the detection (monitoring) of the human body by the passive human sensor is continued (step S608).
Specifically, the control unit 130 continues to acquire the detection result from the passive human sensor 120.

As described above, in the power saving state of the power state, the control unit 130 determines that the passive human sensor 120 detects a human body (YES in step S <b> 602) with respect to the active human sensor 110. Human body detection is performed with the possibility of seating (step S604). Then, the control unit 130 determines whether or not the active human sensor 110 outputs the same detection result as the determination result that the passive human sensor 120 has detected a human body (YES in step S602) (active human human). Determination of whether or not the sensor 110 has detected a human body) is performed (step S605).
When the active human sensor 110 detects a human body (YES in step S605), the display device (video) is based on the determination result (that there is a user (whether or not there is a user)). The display device 100) is shifted to the normal state (step S606), and the operation of the active human sensor 110 is stopped (step S607).
This makes it possible to accurately detect that there is a user (with or without a user) while shortening the period of irradiating the user with infrared rays and making the user uncomfortable as much as possible. The display device (video display device 100) is shifted to the normal state.

In addition, when the passive human sensor 120 detects a human body in the power saving state of the power state (step S <b> 602 -YES), the control unit 130 determines whether the user is seated with respect to the active human sensor 110. Human body detection is performed with a possibility (step S604). Then, the control unit 130 determines whether or not the active human sensor 110 outputs the same detection result as the determination result that the passive human sensor 120 has detected a human body (YES in step S602) (active human human). Determination of whether or not the sensor 110 has detected a human body) is performed (step S605).
If the active human sensor 110 does not detect a human body (step S605-NO), the active type is detected based on the determination result (that there is no user (no user is present)). The operation of the human sensor 110 is stopped (step S603).
Thereby, it is possible to detect that there is no user (no user is present).

As described above, in the present invention, the control shown in FIG. 5 and FIG. 6 is performed so that the user of the video display device 100 is uncomfortable (that is, the infrared ray is irradiated from the video display device 100 when seated). The problem can be solved without reducing the detection accuracy, which is a merit of the active human sensor 110, while shortening the period of time) as much as possible.
Furthermore, in the present invention, in order to reduce the period during which infrared rays are irradiated even when the video display device 100 is in a power saving state, a human sensor that detects infrared rays installed around the video display device 100 is mounted. An effect can also be expected to prevent erroneous detection of the equipment.

Next, a basic configuration example of an embodiment of the present invention will be described with reference to FIG. FIG. 7 is a block diagram showing the basic configuration of the device of the present invention.
7 includes a passive human sensor 120, an active human sensor 110, and a control unit 130.
The passive human sensor 120 detects the presence or absence of a human body by detecting predetermined light emitted from the human body without irradiating infrared rays (predetermined light), and outputs a detection result.
The active human sensor 110 detects the presence or absence of a human body by irradiating predetermined light and detecting the predetermined light reflected from the human body, and outputs a detection result.
The control unit 130 determines whether the active human sensor 110 outputs the same detection result (step S502-YES, step S602-YES) as the detection result of the passive human sensor 120 (step S505, In step S605), based on the determination result, state transition is executed between the normal state and the power saving state of the video display device (step S505—YES → step S506, step S605—YES → step S606).

Here, the control unit 130 in the video display device 100 causes the power state of the video display device to change between a normal state and a power saving state based on the following determination result.
That is, in the normal state, when the passive human sensor 120 cannot detect a human body (step S502—YES), the control unit 130 operates the active human sensor 110 (step S504) to activate the active human sensor. When the human sensor 110 cannot detect a human body (step S505-YES), the power state of the video display device 100 is shifted from the normal state to the power saving state (step S506).
Further, when the active human sensor 110 can detect the human body (step S505-NO), the control unit 130 stops the operation of the active human sensor 110 (step S503).

On the other hand, in the power saving state, when the passive human sensor 120 detects a human body (step S602—YES), the control unit 130 operates the active human sensor 110 (step S604), and the active human sensor 110 When the sensation sensor 110 detects a human body (step S605—YES), the power state of the video display device 100 is shifted from the power saving state to the normal state (step S606).
In addition, when the active human sensor 110 does not detect a human body (step S605—NO), the control unit 130 stops the operation of the active human sensor 110 (step S603).

As described above, according to one aspect of the present invention, the control unit 130 obtains the same detection result (step S502-YES, step S602-YES) as the detection result of the passive human sensor 120 as the active human sensor 110. Is output (step S505, step S605), and based on the determination result, the state transition is executed between the normal state and the power saving state of the video display device (step S505-YES). → Step S506, Step S605-YES → Step S606).
This makes it possible to detect the presence or absence of the user with high accuracy while reducing the period during which the user is in an uncomfortable state by irradiating infrared rays regardless of whether the power saving state or the normal state. Is possible.

In addition, this invention is not limited to the above-mentioned embodiment, The deformation | transformation in the range which can achieve the objective of this invention, improvement, etc. are included in this invention.
For example, in this embodiment, in addition to the active human sensor 110, a passive human sensor 120 is additionally mounted.
Here, it is also possible to substitute for the passive human sensor 120 by using the infrared light receiving unit 211 of the active human sensor 110.
In that case, the infrared ray receiving unit 211 of the active human sensor 110 (such as the infrared sampling period and the detection value gain setting) is appropriately detected from the control unit 130 of the video display device 100. This can be handled by switching and controlling between detecting infrared rays around the environment.

  DESCRIPTION OF SYMBOLS 100 ... Video display apparatus, 110 ... Active human sensor, 120 ... Passive human sensor, 130 ... Control part, 140 ... Power supply, 150 ... Video display part, 160 ... Scaling IC, 170 ... ROM, 180 ... RAM, 211, 221 ... Infrared light receiving part, 212 ... Infrared light emitting part

Claims (5)

A passive human sensor that detects the presence of the human body by detecting the predetermined light emitted from the human body without irradiating the predetermined light, and outputs a detection result;
An active human sensor that detects the presence or absence of the human body by detecting the predetermined light reflected from the human body by irradiating the predetermined light, and outputs a detection result;
It is determined whether the active human sensor outputs the same detection result as the detection result of the passive human sensor, and based on the determination result, the power state of the video display device is set to a normal state and a power saving state. A control unit for executing a state transition between
A video display device comprising: The controller is
In the normal state,
When the passive human sensor cannot detect a human body, the active human sensor is operated,
When the active human sensor cannot detect a human body, the power state of the video display device is shifted from the normal state to the power saving state.
When the active human sensor can detect a human body, the operation of the active human sensor is stopped,
On the other hand, in the power saving state, when the passive human sensor detects a human body, the active human sensor is operated,
When the active human sensor detects a human body, the power state of the video display device is shifted from the power saving state to the normal state,
When the active human sensor does not detect a human body, the operation of the active human sensor is stopped.
The video display device according to claim 1. The controller is
After the state transition is executed between the normal state and the power saving state of the power state of the video display device, the operation of the active human sensor is stopped.
The video display device according to claim 2. The passive human sensor is a sensor that is substituted by using a light receiving unit that receives the predetermined light that the active human sensor has,
The control unit switches and controls the setting of the light receiving unit between the case where the predetermined light emitted is detected and the case where the predetermined light around the environment is detected.
The video display apparatus as described in any one of Claims 1-3. A passive human sensing process in which a passive human sensor detects the presence or absence of the human body by detecting the predetermined light emitted from the human body without irradiating the predetermined light and outputs a detection result; ,
An active human sensing process in which an active human sensor detects the presence of a human body by irradiating the predetermined light and detecting the predetermined light reflected from the human body, and outputs a detection result; ,
The control unit determines whether the active human sensor outputs the same detection result as the detection result of the passive human sensor, and sets the power state of the video display device to a normal state based on the determination result. A control process for executing a state transition between the power saving states;
A video display method.

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