CN106814889B - Mouse and awakening method thereof - Google Patents

Abstract

The invention discloses a mouse and a wake-up method thereof. The mouse comprises a mouse shell, wherein a micro deformation detection area is arranged on the mouse shell, and a micro deformation sensor and a sensor processor are arranged in the mouse shell; the micro deformation sensor is connected with the sensor processor, detects the deformation of the micro deformation detection area to generate a deformation sensing signal, and sends the deformation sensing signal to the sensor processor; and the sensor processor generates a wake-up signal for waking up the mouse according to the deformation sensing signal. According to the invention, the micro deformation detection area is arranged on the mouse shell, so that the mouse is awakened when the micro deformation detection area is deformed, the user can wake up the mouse while contacting the mouse, the user can wake up the mouse without awareness, the awakening mode is novel, the awakening mode of the mouse is enriched, the common touch is prevented from being misjudged as the awakening operation, and the mouse can be accurately awakened.

Description

Mouse and awakening method thereof

Technical Field

The invention relates to the technical field of mouse design, in particular to a mouse and a wake-up method thereof.

Background

The mouse is an input tool with high use frequency in daily life, at present, the wake-up mode of the mouse mainly comprises the steps of swinging the mouse or lightly pressing a key on the mouse to wake up, the wake-up mode is single, and the wake-up mode of swinging or lightly pressing the mouse can easily misjudge common touch as wake-up, so that the problem of false triggering wake-up exists.

Disclosure of Invention

In view of the above description, the invention provides a mouse and a wake-up method thereof, so as to solve the problems that the existing mouse wake-up mode is single, and the error wake-up is easy to be caused by the error touch of the mouse.

In order to achieve the above purpose, the technical scheme of the invention is realized as follows:

in one aspect, the invention provides a mouse, comprising a mouse shell, wherein a micro deformation detection area is arranged on the mouse shell, and a micro deformation sensor and a sensor processor are arranged in the mouse shell;

the micro deformation sensor is connected with the sensor processor, detects the deformation of the micro deformation detection area to generate a deformation sensing signal, and sends the deformation sensing signal to the sensor processor;

and the sensor processor generates a wake-up signal for waking up the mouse according to the deformation sensing signal.

On the other hand, the invention provides a mouse wake-up method, which comprises the following steps:

acquiring deformation sensing signals generated by the micro deformation sensor in real time, and calculating a deformation value of the micro deformation detection area at the current moment according to the acquired deformation sensing signals;

comparing the deformation value at the current moment with the basic deformation value, judging whether the micro deformation detection area at the current moment is deformed, and generating a wake-up signal when the micro deformation detection area at the current moment is deformed.

The embodiment of the invention has the beneficial effects that:

1. the micro deformation detection area is arranged on the mouse shell, so that the mouse is awakened when the micro deformation detection area is deformed, the user can wake up the mouse while contacting the mouse, no extra swinging operation or tapping operation is needed, the user can wake up the mouse without awareness, the awakening mode is novel, and the awakening mode of the mouse is enriched;

2. according to the invention, the specific part of the mouse shell is used as the micro deformation detection area, so that the mouse is awakened when the micro deformation detection area is stressed to deform, the phenomenon that the common touch is misjudged as the awakening operation can be avoided, and the mouse awakening can be accurately carried out.

Drawings

FIG. 1 is a block diagram of a mouse structure according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a mouse according to an embodiment of the present invention;

FIG. 3 is a block diagram of a mouse with a temperature sensor according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a mouse with a temperature detection region and a micro deformation detection region according to an embodiment of the present invention;

FIG. 5 is a perspective view of FIG. 4;

FIG. 6 is a flowchart of a method for waking up a mouse according to an embodiment of the present invention;

fig. 7 is a flowchart of waking up a mouse based on a deformation sensing signal and a temperature sensing signal according to an embodiment of the present invention.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in further detail below with reference to the accompanying drawings, wherein like numerals refer to like structures throughout the drawings.

Example 1

Aiming at the problems that in the prior art, a mouse awakening mode is single, common touch is easily misjudged to be awakened, and the awakening is caused by mistriggering of the mouse, the invention provides a mouse for realizing awakening based on deformation.

FIG. 1 is a block diagram of a mouse according to an embodiment of the present invention, as shown in FIG. 1, the mouse includes a mouse housing, a micro deformation detection area is disposed on the mouse housing, and a micro deformation sensor 11 and a sensor processor 12 are disposed inside the mouse housing; the micro deformation sensor 11 is connected with the sensor processor 12, and the micro deformation sensor 11 detects the deformation of the micro deformation detection area to generate a deformation sensing signal and sends the deformation sensing signal to the sensor processor 12; the sensor processor 12 generates a wake-up signal to wake up the mouse from the deformation sensing signal.

It should be noted that, the micro deformation detection area in this embodiment is understood to be a part of the mouse housing, when the mouse housing is stressed, the mouse housing corresponding to the micro deformation detection area will generate micro deformation, and the magnitude of the deformation is generally 10 ^-1 μm。

Fig. 2 is a schematic diagram of a mouse according to an embodiment of the present invention, as shown in fig. 2, a mouse housing 1 includes a cover 2 contacting a human body, and a micro deformation detection area 3 is located on the cover 2; in general, the surface cover 2 is a curved surface, and the micro deformation detection area 3 is preferably located at the highest stress point of the curved surface cover 2, so that the micro deformation sensor can accurately detect the deformation of the area.

It should be noted that, the present embodiment is not limited to the external structure of the mouse, fig. 2 is only an exemplary illustration of a more common mouse, and the micro deformation detection area may be disposed on other types of mice.

The micro-deformation sensor comprises two sensing plates which are parallel to each other and have a set interval, wherein one sensing plate is used as the positive electrode end of the micro-deformation sensor to be attached to the inner surface of the corresponding surface cover of the micro-deformation detection area, and the other sensing plate is used as the negative electrode end of the micro-deformation sensor to be fixed in the mouse shell through a bracket. As shown in fig. 5, the micro-deformation sensor 11 includes a first sensing plate 111 and a second sensing plate 112, the first sensing plate 111 and the second sensing plate 112 are parallel to each other and have a space, the first sensing plate 111 is used as the positive electrode end of the micro-deformation sensor 11 to be attached to the inner surface of the cover 2, and the second sensing plate 112 is used as the negative electrode end of the micro-deformation sensor 11 to be fixed in the mouse housing 1 through the bracket 4; the installation mode shown in fig. 5 is simple and convenient to install, effectively utilizes the installation space inside the mouse shell, and improves the accuracy of the detection result.

According to the embodiment, the micro deformation detection area is arranged on the mouse shell, the mouse is awakened when the micro deformation detection area deforms, the mouse can be awakened when a user contacts the mouse, extra swinging operation or light pressing operation is not needed, the mouse can be awakened under the condition that the user is unknowingly, the awakening mode is novel, the awakening mode of the mouse is enriched, and the mouse is awakened when the micro deformation detection area is stressed and deformed by taking a specific part of the mouse shell as the micro deformation detection area.

In order to further improve accuracy of mouse wakeup, in a preferred scheme of the embodiment, the auxiliary wakeup component is arranged, and the mouse wakeup is realized by combining deformation of the micro deformation detection area and a triggering event of the auxiliary wakeup component.

In the preferred embodiment, the mouse in fig. 1 further includes an auxiliary wake-up unit, which is connected to the sensor processor 12, and detects whether a trigger event of the auxiliary wake-up unit occurs, and when the trigger event is detected, the auxiliary wake-up unit generates an auxiliary wake-up signal and sends the auxiliary wake-up signal to the sensor processor 12;

the sensor processor 12 generates a wake-up signal to wake up the mouse from the deformation sensing signal and the auxiliary wake-up signal.

In one implementation, the auxiliary wake-up component comprises a temperature detection area arranged on the mouse shell and a temperature sensor arranged inside the mouse shell, wherein the temperature sensor is connected with the sensor processor, detects the temperature of the temperature detection area and generates a temperature sensing signal, and sends the temperature sensing signal to the sensor processor; at this time, the sensor processor generates a wake-up signal for waking up the mouse according to the deformation sensing signal and the temperature sensing signal.

The sensor processor determines whether the micro deformation detection area deforms according to the deformation sensing signal, and determines whether the temperature at the temperature detection area changes according to the temperature sensing signal, and generates a wake-up signal for waking up the mouse when the micro deformation detection area deforms and the temperature at the temperature detection area changes.

In the design process, the position of the mouse shell corresponding to the temperature detection area is provided with a window, a temperature-conducting filler is filled at the window, and illustratively, the temperature-conducting filler is carbon nanotube paper, graphene and the like, the temperature-conducting filler is flush with the surface of the mouse shell, so that the integrity of the appearance of the mouse is ensured, and the temperature sensor is attached to the temperature-conducting filler and arranged inside the mouse shell so as to accurately sense the temperature change of the temperature detection area.

In another implementation scheme, the auxiliary wake-up component is a key arranged on the mouse shell and a key circuit arranged in the mouse shell, the key circuit is connected with the sensor processor, whether the key is pressed or not is detected, a key signal is generated when the key is pressed, and the key signal is sent to the sensor processor; at this time, the sensor processor generates a wake-up signal for waking up the mouse according to the deformation sensing signal and the key signal.

The sensor processor determines whether the micro deformation detection area is deformed according to the deformation sensing signal, and determines whether a key signal from the key circuit is received, if the key signal is received when the micro deformation detection area is deformed, the sensor processor generates a wake-up signal for waking up the mouse.

In another implementation scheme, the auxiliary awakening component is a displacement detection circuit arranged in the mouse shell, the displacement detection circuit is connected with the sensor processor and used for detecting whether the mouse has displacement change, and when the displacement change of the mouse is detected, a displacement signal is generated and sent to the sensor processor; at this time, the sensor processor generates a wake-up signal for waking up the mouse according to the deformation sensing signal and the displacement signal.

The sensor processor determines whether the micro deformation detection area is deformed according to the deformation sensing signal, and determines whether the displacement signal from the displacement detection circuit is received, and if the displacement signal is received when the micro deformation detection area is deformed, the sensor processor generates a wake-up signal for waking up the mouse.

Comparing the three implementation schemes, when the auxiliary wake-up component is a temperature detection area arranged on the mouse shell and a temperature sensor arranged inside the mouse shell, the sensor processor can generate a wake-up signal according to the deformation sensing signal and the temperature sensing signal, and wake-up of the mouse can be completed when a user touches the mouse, no additional operation is needed, and the wake-up of the mouse can be completed under the condition that the user is unconscious; in the other two implementations, the user is required to purposely press the mouse button or swing the mouse, and the wake-up cannot be completed without the user being aware of it, so the auxiliary wake-up component is preferably designed to be a temperature detection area and a temperature sensor.

In the three implementations, the sensor processor generates a wake-up signal for waking up the mouse according to the deformation sensing signal and an auxiliary wake-up signal (a temperature sensing signal or a key signal or a displacement signal); obviously, according to the use needs, in practical application, the sensor processor can also generate wake-up signals for waking up the mouse according to more than three signals (namely deformation sensing signals and more than two auxiliary wake-up signals), and accordingly, the auxiliary wake-up component comprises a temperature detection area arranged on the mouse shell, a temperature sensor arranged inside the mouse shell, a key arranged on the mouse shell, a key circuit arranged inside the mouse shell and one or more of displacement detection circuits arranged inside the mouse shell.

To describe the advantageous effects of the present embodiment in detail, a specific implementation of the present embodiment will be described below.

Fig. 3 is a block diagram of a mouse structure with a temperature sensor according to an embodiment of the present invention, fig. 4 is a schematic diagram of a mouse with a temperature detection area and a micro deformation detection area according to an embodiment of the present invention, and fig. 5 is a perspective view of fig. 4.

Referring to fig. 3 to 5, in this specific implementation scheme, a micro deformation detection area 3 and a temperature detection area 5 are provided on a mouse housing 1, a micro deformation sensor 11, a temperature sensor 13 and a sensor processor 12 are provided inside the mouse housing 1, the micro deformation sensor 11 and the temperature sensor 13 are respectively connected with the sensor processor 12, and in practical application, the micro deformation sensor 11 may be an LDC1612 sensor of TI company.

The micro deformation sensor 11 detects the deformation of the micro deformation detection area to generate a deformation sensing signal, and sends the deformation sensing signal to the sensor processor 12; the temperature sensor 13 detects the temperature of the temperature detection area 5 to generate a temperature sensing signal and sends the temperature sensing signal to the sensor processor 12;

the sensor processor 12 generates a wake-up signal to wake up the mouse from the deformation sensing signal and the temperature sensing signal.

Referring to fig. 4 and 5, the mouse housing 1 includes a cover 2 contacting with a human body, and the micro deformation detection area 3 and the temperature detection area 5 are both located on the cover 2, wherein the cover 2 is a curved surface, as shown in fig. 4, the micro deformation detection area 3 is located at the highest stress point position of the curved surface cover 2, and the temperature detection area 5 is located on the curved surface cover near the micro deformation detection area 3, that is, the micro deformation detection area is located adjacent to the temperature detection area, so as to ensure that the deformation and the temperature detected are both from the palm, and prevent misoperation. In fig. 4, the micro deformation detection area 3 and the temperature detection area 5 are shown as circles, and the area of the micro deformation detection area 3 is larger than the area of the temperature detection area 5, and the invention does not limit the shape of the micro deformation detection area and the shape of the temperature detection area 5, and does not limit the size relationship of the two detection areas.

It should be noted that, in the present invention, the micro deformation detection area 3 is formed by a mouse housing, and when the micro deformation detection area 3 is stressed (i.e. held by a user), deformation of about 0.2 μm can be generated; the temperature detection area 5 is formed by a temperature-conducting filler, the position, corresponding to the temperature detection area 5, of the face cover 2 of the mouse shell 1 is windowed, the windowed position is filled with the temperature-conducting filler, the temperature-conducting filler is illustratively carbon nanotube paper, graphene and the like, the temperature-conducting filler is flush with the outer surface of the face cover 2, the integrity of the appearance of the mouse is guaranteed, and the temperature sensor 13 is attached to the temperature-conducting filler and arranged inside the mouse shell 1 so as to accurately sense the temperature change of the temperature detection area 5.

As shown in fig. 5, in the present embodiment, the sensing plates 111, 112 of the micro-deformation sensor 11 are parallel to each other with a set interval, typically less than 1mm, and the sensing plate 111 is attached to the inner surface of the cover 2 as the positive electrode end of the micro-deformation sensor 11, and the sensing plate 112 is fixed in the mouse housing 1 as the negative electrode end of the micro-deformation sensor 11 by the bracket 4.

When the mouse in the specific implementation scheme is in a dormant state, the micro deformation sensor 11 senses the deformation of the micro deformation detection area 3 in real time, and generates a deformation sensing signal to be sent to the sensor processor 12; the temperature sensor 13 senses the temperature of the temperature detection area 5 in real time, generates a temperature sensing signal synchronous with the deformation sensing signal and sends the temperature sensing signal to the sensor processor 12, the sensor processor 12 judges whether the micro deformation detection area deforms according to the deformation sensing signal and judges whether the temperature of the temperature detection area changes according to the synchronous temperature sensing signal, when the micro deformation detection area deforms and the temperature of the temperature detection area changes, the sensor processor 12 generates a wake-up signal for waking up the mouse and sends the wake-up signal to the main control chip 14 of the mouse to wake up the main control chip 14 of the mouse, so that the mouse processes a normal working mode.

Example two

Based on the same technical concept as the first embodiment, the present embodiment also provides a method for waking up a mouse, and the structure of the mouse in the present embodiment is the same as that of the first embodiment, and will not be described herein.

Fig. 6 is a flowchart of a method for waking up a mouse according to an embodiment of the present invention, as shown in fig. 6, where the method includes:

s600, acquiring deformation sensing signals generated by the micro deformation sensor in real time, and calculating deformation values of the micro deformation detection area at the current moment according to the deformation sensing signals acquired at the same moment.

S620, comparing the deformation value at the current moment with the basic deformation value, judging whether the micro deformation detection area at the current moment is deformed, and generating a wake-up signal when the micro deformation detection area at the current moment is deformed.

The present embodiment obtains a basic deformation value by:

calculating a deformation value of the micro deformation detection area corresponding to the mouse entering a standby mode, and recording the calculated deformation value as a basic deformation value; or, the initialized deformation value of the micro deformation detection area is taken as the basic deformation value.

In a preferred aspect of this embodiment, when the micro deformation detection area at the current moment is deformed, the method in fig. 6 further includes:

and detecting whether a trigger event of the auxiliary wake-up component exists, generating a wake-up signal when the trigger event is detected, and otherwise, not generating the wake-up signal.

Illustratively, the auxiliary wake-up component is a temperature detection area disposed on the mouse housing and a temperature sensor disposed inside the mouse housing, and the method in fig. 6 is specifically as follows:

acquiring deformation sensing signals generated by the micro deformation sensor in real time, and calculating a deformation value of the micro deformation detection area at the current moment according to the acquired deformation sensing signals; the temperature sensing signals generated by the temperature sensor in real time are collected, and the temperature value of the current moment of the temperature detection area is calculated according to the collected temperature sensing signals;

and comparing the deformation value and the temperature value at the current moment with the basic deformation value and the basic temperature value respectively, judging whether the micro deformation detection area at the current moment deforms, judging whether the temperature of the temperature detection area at the current moment changes, and generating a wake-up signal when the micro deformation detection area at the current moment deforms and the temperature of the temperature detection area changes.

In order to specifically explain the implementation manner of performing mouse wakeup by combining the triggering event of the auxiliary wakeup component in this embodiment, this embodiment is described by the following specific implementation scheme.

In this specific implementation scheme, supplementary wake-up part is including setting up the temperature detection region on the mouse casing and setting up the inside temperature sensor of mouse casing, generates wake-up signal according to deformation induction signal and temperature induction signal.

Fig. 7 is a flowchart of waking up a mouse based on a deformation sensing signal and a temperature sensing signal according to the present embodiment, where, as shown in fig. 7, the waking up process is as follows:

s700, determining a basic deformation value and a basic temperature value.

The deformation value and the temperature value of the micro deformation detection area and the temperature detection area corresponding to the mouse entering the standby mode can be calculated, and the calculated deformation value and the calculated temperature value are recorded as a basic deformation value and a basic temperature value;

or, the initialized deformation value of the micro deformation detection area is taken as a basic deformation value, and the normal temperature or the room temperature is taken as a basic temperature value.

S710, detecting the mouse in real time, and collecting synchronous deformation sensing signals and temperature sensing signals.

The micro deformation sensor senses the deformation of the micro deformation detection area in real time and generates a deformation sensing signal; the temperature sensor senses the temperature at the temperature detection area in real time and generates a temperature sensing signal.

S720, judging whether the micro deformation detection area is deformed, executing step S730 when the micro deformation detection area is deformed, otherwise returning to step S710, and continuously detecting the mouse.

Illustratively, the deformation value at the current moment is compared with the basic deformation value, and whether the micro deformation detection area at the current moment is deformed or not is judged.

In order to avoid calculation errors, when the difference between the deformation value at the current moment and the basic deformation value is larger than the deformation tolerance error, the deformation of the micro deformation detection area at the current moment is determined.

S730, judging whether the temperature at the temperature detection area changes, executing step S740 when the temperature at the temperature detection area changes, otherwise returning to step S710, and continuously detecting the mouse.

Illustratively, the temperature value at the current time is compared with the base temperature value, and it is determined whether the temperature at the temperature detection area at the current time is changed. In order to avoid calculation errors, when the difference value between the temperature value at the current moment and the basic temperature value is larger than the temperature tolerance error, the temperature at the temperature detection area at the current moment is determined to change.

Note that, the execution sequence of step S720 and step S730 is not limited in this embodiment, and as shown in fig. 7, step S720 may be executed first, step S730 may be executed later, or step S730 may be executed first, and step S720 may be executed later; step S720 and step S730 may also be carried out simultaneously.

S740, generating a wake-up signal to wake up the mouse.

From the above, the wakeup of the mouse is realized through steps S700 to S740, and the wakeup can be triggered only when the deformation and the temperature of the mouse change simultaneously.

The specific implementation manner of each step in the method embodiment of the present invention may refer to the specific content of the mouse embodiment of the present invention, and will not be described herein.

The foregoing is merely a specific embodiment of the invention and other modifications and variations can be made by those skilled in the art in light of the above teachings. It is to be understood by persons skilled in the art that the foregoing detailed description is provided for the purpose of illustrating the invention more fully, and that the scope of the invention is defined by the appended claims.

Claims (10)

1. The mouse comprises a mouse shell, and is characterized in that a micro-deformation detection area is arranged on the mouse shell, the mouse shell comprises a surface cover contacted with a human body, the micro-deformation detection area is positioned on the surface cover, the micro-deformation sensor comprises two sensing plates which are parallel to each other and have a space, one sensing plate is used as the positive electrode end of the micro-deformation sensor to be attached to the inner surface of the surface cover corresponding to the micro-deformation detection area, and the other sensing plate is used as the negative electrode end of the micro-deformation sensor to be fixed in the mouse shell through a bracket;

a micro deformation sensor and a sensor processor are arranged in the mouse shell; the micro deformation sensor is connected with the sensor processor, detects deformation of the micro deformation detection area to generate a deformation sensing signal, and sends the deformation sensing signal to the sensor processor;

and the sensor processor generates a wake-up signal for waking up the mouse according to the deformation sensing signal.

2. The mouse of claim 1, further comprising an auxiliary wake-up component;

the auxiliary wake-up component is connected with the sensor processor, detects whether a trigger event of the auxiliary wake-up component occurs, and generates an auxiliary wake-up signal and sends the auxiliary wake-up signal to the sensor processor when the trigger event is detected;

and the sensor processor generates a wake-up signal for waking up the mouse according to the deformation sensing signal and the auxiliary wake-up signal.

3. The mouse of claim 2, wherein the auxiliary wake-up component comprises a temperature detection area disposed on the mouse housing and a temperature sensor disposed inside the mouse housing;

the temperature sensor is connected with the sensor processor, detects the temperature of the temperature detection area, generates a temperature sensing signal and sends the temperature sensing signal to the sensor processor.

4. The mouse of claim 3, wherein a window is provided at a position of the mouse housing corresponding to the temperature detection area, and a temperature-guiding filler is filled in the window, and the temperature-guiding filler is flush with the surface of the mouse housing; the temperature sensor is attached to the temperature-conducting filler and arranged inside the mouse shell.

5. A mouse according to claim 2 or 3, wherein the auxiliary wake-up unit comprises a key arranged on the mouse housing and a key circuit arranged inside the mouse housing, the key circuit being connected to the sensor processor for detecting whether the key is pressed, generating a key signal when the key is pressed, and transmitting the key signal to the sensor processor;

and/or the auxiliary awakening component comprises a displacement detection circuit arranged in the mouse shell, wherein the displacement detection circuit is connected with the sensor processor and used for detecting whether the mouse has displacement change or not, and when the mouse is detected to have displacement change, a displacement signal is generated and sent to the sensor processor.

6. The mouse of claim 1, wherein the cover is a curved cover, and the micro-deformation detection area is located at a highest stress point of the curved cover.

7. A method of waking up a mouse, wherein the mouse is a mouse as claimed in any one of claims 1 to 6, the method comprising:

acquiring deformation sensing signals generated by the micro deformation sensor in real time, and calculating a deformation value of the micro deformation detection area at the current moment according to the acquired deformation sensing signals;

comparing the deformation value at the current moment with the basic deformation value, judging whether the micro deformation detection area at the current moment is deformed, and generating a wake-up signal when the micro deformation detection area at the current moment is deformed.

8. The mouse wakeup method according to claim 7, wherein the basic deformation value is obtained by:

calculating a deformation value of the micro deformation detection area corresponding to the mouse entering a standby mode, and recording the calculated deformation value as a basic deformation value; or, the initialized deformation value of the micro deformation detection area is taken as the basic deformation value.

9. The method of claim 7, wherein when the micro-deformation detection area at the current time is deformed, the method further comprises:

and detecting whether a trigger event of the auxiliary wake-up component exists, generating a wake-up signal when the trigger event is detected, and otherwise, not generating the wake-up signal.

10. The method of claim 9, wherein the auxiliary wake-up component includes a temperature detection area disposed on the mouse housing and a temperature sensor disposed inside the mouse housing, the method comprising:

acquiring deformation sensing signals generated by the micro deformation sensor in real time, and calculating a deformation value of the micro deformation detection area at the current moment according to the acquired deformation sensing signals; the temperature sensing signals generated by the temperature sensor in real time are collected, and the temperature value of the current moment of the temperature detection area is calculated according to the collected temperature sensing signals;

and comparing the deformation value and the temperature value at the current moment with the basic deformation value and the basic temperature value respectively, judging whether the micro deformation detection area at the current moment deforms, judging whether the temperature of the temperature detection area at the current moment changes, and generating a wake-up signal when the micro deformation detection area at the current moment deforms and the temperature of the temperature detection area changes.