JP2021034984A - Electronic devices, control methods for electronic devices, and control programs for electronic devices - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic device capable of turning on / off a power source as intended by a user. SOC2 of a wearable speaker 1 puts the wearable speaker 1 into a 0th sleep state in a standby state when the power is turned off by a power button 8 when the power of the wearable speaker 1 is on. Further, when the wearable speaker 1 is in the 0th sleep, the SoC2 sets the wearable speaker 1 in the first sleep in the standby state when the proximity sensor 7 does not detect the proximity. Further, the SoC2 turns on the power of the wearable speaker 1 when the proximity sensor 7 detects the proximity when the wearable speaker 1 is in the first sleep. [Selection diagram] Fig. 5

Description

The present invention relates to a wearable type electronic device worn on a human body, a control method for the electronic device, and a control program for the electronic device.

In recent years, for example, wearable type electronic devices worn on the human body such as arms have appeared. In such a wearable type electronic device, it is very convenient if the power is automatically turned on when the user wears it on the human body. The applicant has applied for an invention in which the power of an electronic device is automatically turned on by using two types of sensors (see Patent Document 1).

JP-A-2019-110524

In the invention disclosed in Patent Document 1, for example, when the acceleration sensor detects the movement and the proximity sensor detects the proximity, the power of the electronic device is turned on. If the electronic device is a wearable type electronic device worn around the neck, even if the user performs an operation to turn off the power (operation of the power button) while the electronic device is hung on the neck, the proximity is close. There is a problem that the power is turned on because the proximity is detected by the sensor.

An object of the present invention is to provide an electronic device capable of turning on / off a power source as intended by a user.

The electronic device of the first invention includes a second sensor for detecting proximity, a button for receiving power off, and a control unit, and the control unit is said to be described when the power of its own device is on. When the power is turned off by the button, the own device is put into the first state in the standby state, and when the own device is in the first state, if the second sensor does not detect proximity, the own device is put in the standby state. In a second state,
When the second sensor detects proximity when the own device is in the second state, the power of the own device is turned on.

In the present invention, when the power of the own device is on and the power is turned off by the button, the control unit puts the own device in the first state (standby state). Then, when the own device is in the second state (standby state), the control unit turns on the power of the own device when the second sensor detects the proximity. As a result, when the first state is reached by operating the button, the power of the electronic device is not turned on even if the proximity is detected by the second sensor. Further, when the proximity is not detected by the second sensor after the first state is reached by button operation and the electronic device is in the second state, if the proximity is detected by the second sensor, the power supply of the electronic device is supplied. However, it turns on. Therefore, immediately after the user turns off the power of the electronic device, the power does not turn on, and after the user turns off the power of the electronic device, moves the electronic device away from the user, and then brings it closer to the user again. When the proximity is detected, the power of the electronic device is turned on. As described above, according to the present invention, it is possible to turn on / off the power of the electronic device as intended by the user.

The electronic device of the second invention is the electronic device of the first invention, in which the control unit is the own device when the first sensor does not detect proximity for a predetermined time when the own device is in the first state. Is the second state.

The electronic device of the third invention further includes a first sensor for detecting motion in the electronic device of the first or second invention, and the control unit is the first sensor when the own device is in the standby state. When it detects movement, it puts its own device in the second state.

The electronic device of the fourth invention is the electronic device of the third invention, in which the first sensor is on, the second sensor is off, and the control unit is in the standby state when the own device is in the standby state. When the own device is in the standby state and the first sensor detects movement, the second sensor is turned on.

The electronic device of the fifth invention is the electronic device of any one of the first to fourth inventions, wherein the control unit makes a wireless connection with another device after turning on the power of the own device. It is a feature.

The electronic device of the sixth invention is the electronic device of any one of the third to fifth inventions, wherein the first sensor is an acceleration sensor.

The electronic device of the seventh invention is the electronic device of any one of the first to sixth inventions, wherein the second sensor is a proximity sensor.

The electronic device control method of the eighth invention is a control method of an electronic device including a second sensor for detecting proximity and a button for receiving power off, and when the power of the own device is on. When the power is turned off by the button, the own device is set to the first state, and when the own device is in the first state, when the second sensor does not detect proximity, the own device is set to the second state. When the second sensor detects proximity when the own device is in the second state, the power of the own device is turned on.

The electronic device control program of the ninth invention is a control program for an electronic device including a second sensor for detecting proximity, a button for receiving power off, and a control unit, and the control unit includes the control unit. When the power of the own device is on, when the power is turned off by the button, the own device is put into the first state, and when the own device is in the first state, the second sensor does not detect proximity. In this case, the own device is put into the second state, and when the own device is in the second state, when the second sensor detects proximity, the power of the own device is turned on.

According to the present invention, it is possible to turn on / off the power of the electronic device as intended by the user.

It is a perspective view which shows the appearance of the wearable speaker which concerns on embodiment of this invention. It is a block diagram which shows the structure of the wearable speaker which concerns on embodiment of this invention. It is a figure which shows the operation of an acceleration sensor and the like. It is a figure which shows the transition state of the power supply of the conventional wearable speaker. It is a figure which shows the transition state of the power supply of a wearable speaker.

Hereinafter, embodiments of the present invention will be described. FIG. 1 is a perspective view showing the appearance of a wearable speaker according to an embodiment of the present invention. As shown in FIG. 1, the wearable speaker 1 (electronic device) includes a substantially U-shaped housing 9, and is worn around the user's neck. That is, the wearable speaker 1 is a wearable type speaker worn on the user's neck. The housing 9 is made of resin, for example.

FIG. 2 is a block diagram showing a configuration of a wearable speaker according to an embodiment of the present invention. The wearable speaker 1 performs wireless communication with the smartphone 101 in accordance with the Bluetooth (registered trademark) (hereinafter referred to as “BT”) standard. As shown in FIG. 2, the wearable speaker 1 includes a SoC (System on Chip) 2, an amplification unit 3, speaker units 4, 5, an acceleration sensor 6, a proximity sensor 7, a power button 8, and the like.

The SoC2 (control unit) has a CPU (Central Processing Unit), a DSP (Digital Signal Processor), a memory, and the like, and controls each unit constituting the wearable speaker 1. In addition, the SoC2 has a BT communication function and performs BT wireless communication with the smartphone 101. The SoC2 receives, for example, an audio signal from the smartphone 101. The SoC2 outputs the audio signal received from the smartphone 101 to the amplification unit 3.

An I2S format audio signal is output from SoC2 to the amplification unit 3. The amplification unit 3 amplifies the audio signal and outputs the amplified audio signal to the speaker units 4 and 5. The L channel audio signal is output to the speaker unit 4. The R channel audio signal is output to the speaker unit 5. The speaker units 4 and 5 output voice to the outside based on the voice signal. In this way, the wearable speaker 1 reproduces the voice based on the voice signal output from the smartphone 101.

FIG. 3 is a diagram showing the operation of the acceleration sensor and the like. The acceleration sensor 6 (first sensor) detects the movement of the wearable speaker 1. The acceleration sensor 6 is, for example, on the tip end side of any one of the substantially U-shaped housings 8 and is provided inside the housing 8. The acceleration sensor 6 is a 3-axis acceleration sensor. The acceleration sensor 6 can set a threshold value for detecting the movement, and the SoC2 sets the threshold value. The acceleration sensor 6 stands by in a low power consumption state regardless of whether the power of the wearable speaker 1 is turned on or off, and when an acceleration exceeding the threshold value is generated, an event pulse is generated. For example, when the user picks up the wearable speaker 1 placed on a table or the like, acceleration equal to or higher than the threshold value is generated, and the acceleration sensor 6 detects the movement. In other words, the accelerometer 6 detects an action in which the user picks up the wearable speaker 1. The acceleration sensor 6 consumes less power than the proximity sensor 7. The acceleration sensor 6 detects the movement of the wearable speaker 1 when the threshold value is exceeded due to a change in acceleration.

The proximity sensor 7 (second sensor) detects the proximity of an object such as clothes and a part of the human body such as the neck. The proximity sensor 7 is provided in the housing 8 at a position facing the neck with the wearable speaker 1 hung on the neck. The proximity sensor 7 is a reflective optical proximity sensor that emits infrared rays and detects the proximity of an object or the like by the reflected light. The proximity sensor 7 can set a threshold value for detecting proximity, and the SoC2 sets the threshold value. For example, when the user wears the wearable speaker 1 on the neck, the neck is close to the proximity sensor 7, so that the proximity sensor 7 detects the proximity of the neck. In other words, the proximity sensor 7 detects a state in which the user wears the wearable speaker 1 around his / her neck. Further, the proximity sensor 7 consumes more power than the acceleration sensor 6. The power button 8 is a button for receiving the power off.

FIG. 4 is a diagram showing a transition state of the power supply of the conventional wearable speaker. In the conventional wearable speaker, the SoC2 shifts the wearable speaker 1 to the first sleep when the power is turned off by the operation button 9 when the power is on. If the proximity sensor 7 detects proximity during the first sleep, the SoC2 is interrupted and the operation state is set. That is, the SoC2 turns on the power of the wearable speaker 1. Therefore, when the user turns off the power of the wearable speaker 1 with the power button 9 while the wearable speaker 1 is hung on the neck, the proximity sensor 7 detects the proximity and the power of the wearable speaker 1 is turned on. .. The transition from the power-on state to the first sleep includes a non-connection timeout with the smartphone 101, and is not an automatic power-off transition.

FIG. 5 is a diagram showing a transition state of the power supply of the wearable speaker. In the present embodiment, when the power of the wearable speaker 1 is on, the SoC2 shifts the wearable speaker 1 to the 0th sleep (first state) when the power is turned off by the operation button 9. When the wearable speaker 1 is in the 0th sleep, the SoC2 uses the wearable speaker 1 when the proximity sensor 7 does not detect the proximity and the acceleration sensor 6 does not detect the movement for a predetermined time (for example, 8 seconds). It shifts to the first sleep (second state). Here, the 0th sleep is a standby state of the wearable speaker 1, and the 1st sleep is a standby state of the wearable speaker 1 which is different from the 0th sleep.

At the time of the first sleep, if the proximity sensor 7 does not detect the proximity, it remains in the first sleep. If the proximity sensor 7 detects proximity during the first sleep, the SoC2 is interrupted and the operation state is set. That is, the SoC2 turns on the power of the wearable speaker 1. After turning on the power of the wearable speaker 1, the SoC2 makes a wireless connection (BT) with the smartphone 101 (another device) that has been paired. When the power of the wearable speaker 1 is on, if the proximity sensor 7 detects proximity, the power of the wearable speaker 1 remains on.

When the power of the wearable speaker 1 is turned on, if the proximity sensor 7 does not detect the proximity for a predetermined time, the SoC2 shifts the wearable speaker 1 to the first sleep (timeout). If the proximity sensor 7 does not detect proximity for a predetermined time during the first sleep, the SoC2 shifts the wearable speaker 1 to the second sleep.

The second sleep corresponds to the standby state of the wearable speaker 1, and is a state in which the wearable speaker 1 is operating with low power consumption. In the second sleep, only the accelerometer 6 is on, and the others are in the sleep state. For example, the accelerometer 6 operates every second (intermittent operation). In the second sleep (the wearable speaker 1 is in the standby state), if the acceleration sensor 6 does not detect the movement, the second sleep remains. If the accelerometer 6 detects movement during the second sleep, the SoC2 shifts the wearable speaker 1 to the first sleep. That is, the SoC2 turns on the proximity sensor 7, sets the proximity sensor 7 to operate every second, and sleeps. In the first sleep, the acceleration sensor 6 and the proximity sensor 7 are operated every second.

Here, the "standby state" is a state in which the wearable speaker 1 is energized but is in a low power consumption mode, and the SoC2 (control unit) is operating at a low clock (corresponding to the second sleep). ). Further, in the state of "power on of own device", the wearable speaker 1 is energized and is in the normal mode, and the SoC2 (control unit) is operated by the normal clock.

Further, when the wearable speaker 1 is in the 0th sleep, the acceleration sensor 6 shifts the wearable speaker 1 to the second sleep and waits for the motion detection when the acceleration sensor 6 does not detect the movement for a predetermined time (for example, 1 hour). .. It is assumed that the wearable speaker 1 is hung on the neck of the mannequin. In SoC2, when the wearable speaker 1 is in the 0th sleep, proximity and movement are not detected, and when the wearable speaker 1 is not shifted to the 1st sleep and the 2nd sleep, for example, after 48 hours, a timeout occurs. Move to full power off (shutdown).

As described above, in the present embodiment, when the power of the wearable speaker 1 is on and the power button 8 receives the power off, the SoC2 sets the wearable speaker 1 to the 0th sleep (first state). To do. Then, the SoC2 turns on the power of the wearable speaker 1 when the proximity sensor 7 detects the proximity when the wearable speaker 1 is in the first sleep (second state). As a result, when the 0th sleep is entered by operating the power button 8, the power of the wearable speaker 1 is not turned on even if the proximity sensor 7 detects the proximity. Further, when the proximity sensor 7 does not detect the proximity after the operation of the power button 8 causes the 0th sleep, and the wearable speaker 1 goes into the first sleep, the proximity sensor 7 detects the proximity. The power of the wearable speaker 1 is turned on. Therefore, immediately after the user turns off the power of the wearable speaker 1, the power does not turn on, and after the user turns off the power of the wearable speaker 1 and moves the wearable speaker 1 away from the user (from the neck). After removing it), bring it closer to the user (wear it around the neck), and when proximity is detected, the wearable speaker 1 is turned on. As described above, according to the present embodiment, it is possible to turn on / off the power of the wearable speaker 1 as intended by the user.

Although the embodiments of the present invention have been described above, the embodiments to which the present invention can be applied are not limited to the above-described embodiments, and as illustrated below, appropriate as long as the gist of the present invention is not deviated. It is possible to make changes.

In the above-described embodiment, the SoC2 controls the acceleration sensor 6 and the proximity sensor 7, and based on the motion detection by the acceleration sensor 6, the proximity sensor 7 is turned on / off, and the motion is detected by the acceleration sensor 6. The power supply of the wearable speaker 1 is controlled based on the detection of the movement by the proximity sensor 7. Not limited to this, a microcomputer or the like different from the SoC2 may perform the above control, or the microcomputer or the like and the SoC2 may cooperate to perform the above control.

In the above-described embodiment, the wearable speaker 1 worn on the neck is exemplified as a wearable type electronic device worn on the human body. Not limited to this, it may be a wristwatch-type wearable type electronic device worn on the wrist. Further, it may be a headset, earphones, or headphone-type wearable type electronic device worn on the ear.

In the above-described embodiment, the acceleration sensor 6 is exemplified as the sensor (first sensor) for detecting the movement. Not limited to this, other sensors that detect movement may be used. Further, as a sensor for detecting proximity (second sensor), the proximity sensor 7 is exemplified. Not limited to this, other sensors that detect proximity, such as an illuminance sensor, may be used.

INDUSTRIAL APPLICABILITY The present invention can be suitably adopted for a wearable type electronic device worn on a human body, a control method for the electronic device, and a control program for the electronic device.

1 Wearable speaker (electronic device)
2 SoC (control unit)
6 Accelerometer (1st sensor)
7 Proximity sensor (second sensor)
8 Power button 9 Housing

Claims (19)

The first sensor that detects movement and
The second sensor that detects proximity and
When the own device is in the standby state, the control unit that turns on the power of the own device when the first sensor detects the movement and the second sensor detects the proximity.
An electronic device characterized by being equipped with. When the own device is in the standby state, the first sensor is on, the second sensor is off, and so on.
The electronic device according to claim 1, wherein the control unit turns on the second sensor when the first sensor detects movement when the own device is in the standby state. The electronic device according to claim 2, wherein the second sensor consumes more power than the first sensor. The control unit is characterized in that when the first sensor detects movement and the second sensor detects proximity within a predetermined time, the power of its own device is turned on. The electronic device according to any one of 3. The electronic device according to any one of claims 1 to 4, wherein the control unit makes a wireless connection with another device after turning on the power of the own device. The control unit is characterized in that when the power of the own device is on and the second sensor does not detect proximity for a predetermined time, the second sensor is turned off and the own device is put into a standby state. The electronic device according to any one of claims 1 to 5. The electronic device according to any one of claims 1 to 6, wherein the control unit sets a threshold value for detecting the movement of the first sensor. The electronic device according to any one of claims 1 to 7, wherein the control unit sets a threshold value for detecting proximity by the second sensor. The electronic device according to any one of claims 1 to 8, wherein the first sensor is an acceleration sensor. The electronic device according to any one of claims 1 to 9, wherein the second sensor is a proximity sensor. The electronic device according to any one of claims 1 to 10, wherein the electronic device is a wearable type electronic device worn on a human body. The electronic device according to any one of claims 1 to 11, characterized in that it is a wearable type electronic device worn on the neck. The electronic device according to any one of claims 1 to 12, further comprising a substantially U-shaped housing. The electronic device according to any one of claims 1 to 11, characterized in that it is a wearable type electronic device worn on an arm. The electronic device according to any one of claims 1 to 11, wherein the electronic device is a wearable type electronic device worn on an ear. The first sensor that detects movement and
It is a control method of an electronic device including a second sensor for detecting proximity.
A method for controlling an electronic device, which comprises turning on the power of the own device when the first sensor detects movement and the second sensor detects proximity when the own device is in a standby state. .. The first sensor that detects movement and
The second sensor that detects proximity and
A control program for an electronic device including a control unit.
When the own device is in the standby state, when the first sensor detects movement and the second sensor detects proximity, the control unit is made to turn on the power of the own device. Equipment control program. When the own device is in the standby state, the control unit turns on the power of the own device when the first sensor detects the movement, the second sensor detects the proximity, and recognizes a predetermined voice. The electronic device according to any one of claims 1 to 15, wherein the electronic device is characterized by the above. With the sensor
When the own device is in the standby state, when the sensor detects and recognizes a predetermined voice, the control unit that turns on the power of the own device and
An electronic device characterized by being equipped with.