WO2017107562A1 - Intelligent starting up system of mobile terminal and method therefor - Google Patents

Abstract

An intelligent starting up system of a mobile terminal and a method therefor. The method comprises: when a finger of a user is detected to be in a starting up area of a mobile terminal (S100), detecting the distance between the user finger and the starting up area and outputting a distance value (S200), and detecting the time period for which the user finger stays within the starting up area (S300), and when the distance value is received and the time period for which the user finger stays in the starting up area is greater than a pre-set time period, controlling the mobile terminal to enter a starting up state (S400).

Description

Mobile terminal intelligent booting system and method thereof Technical field

The present invention relates to the field of mobile terminal technologies, and in particular, to a mobile terminal intelligent booting system and a method thereof.

Background technique

At present, the booting mode of the smart mobile terminal is singular. With the development of the smart mobile terminal, the smart mobile terminal as a platform for the innovation technology display should provide the user with a richer and more convenient booting mode.

The button activation is a commonly used startup method for smart mobile terminals. It is singular and tedious, and cannot reflect the experience brought by the new technology to the user. The use of the power button for a long time is very easy to damage and cannot be adapted to the smart mobile terminal. rapid development.

Therefore, the prior art has yet to be improved and improved.

technical problem

In view of the above deficiencies of the prior art, an object of the present invention is to provide a smart terminal booting system and method thereof, which can detect a distance between a user's finger and a booting area of the mobile terminal and a user's finger in the booting area. The time of internal control controls the mobile terminal to be powered on, without using the button to boot, which improves the life of the power button of the mobile terminal, and brings a brand new booting experience to the consumer.

Technical solution

In order to achieve the above object, the present invention adopts the following technical solutions:

The invention provides a smart booting method for a mobile terminal, which comprises the following steps:

When the infrared sensing module detects that the user's finger is located in the booting area of the mobile terminal, outputting a digital level signal;

The distance between the user's finger and the booting area is detected by the infrared ranging module, and the distance value is output;

When the digital detection signal output by the infrared sensing module is received by the clock detecting module, detecting the time that the user's finger is held in the booting area;

Receiving the distance value and the holding time by the power-on control module, when the distance between the user finger and the booting area is less than a preset distance, and the time that the user's finger remains in the booting area is greater than the pre- When the time is set, the mobile terminal is controlled to enter a power on state.

Preferably, after the output distance value, and before the receiving, by the clock detection module, the digital level signal output by the infrared sensing module, the method further includes: receiving, by the infrared temperature detecting module, the output of the infrared sensing module The digital level signal detects the temperature of the user's finger.

Preferably, the infrared temperature detecting module detects the temperature of the user's finger when receiving the digital level signal output by the infrared sensing module, including:

The infrared energy focusing unit detects the infrared energy radiated by the user's finger when receiving the high level output by the infrared sensing module;

Converting the infrared energy into a voltage signal by a voltage conversion unit;

The voltage signal is converted to temperature by a temperature conversion unit and output to the power-on control module.

Preferably, the clock detection module detects the time that the user's finger is held in the boot area when receiving the digital level signal output by the infrared sensing module, including:

The clock detecting unit outputs a clock pulse signal when receiving the low level output by the infrared sensing module;

The duration of the high level of the clock signal is recorded by the clock counting unit and output to the power-on control module.

Preferably, before the outputting the digital level signal, when the infrared sensing module detects that the user's finger is located in the booting area of the mobile terminal, the method further includes:

When the air pressure sensor module senses that the air pressure in the power-on area changes, the air pressure change in the power-on area is converted into a weak voltage signal, and is output to the voltage amplifier module;

The weak voltage signal is amplified by the voltage amplifier module, and then filtered by the voltage stabilization filter module to output a stable voltage to the infrared sensing module.

The invention also provides a smart booting method for a mobile terminal, which comprises the following steps:

When the infrared sensing module detects that the user's finger is located in the booting area of the mobile terminal, the digital level signal is output;

The infrared distance measuring module detects a distance between the user's finger and the booting area and outputs a distance value;

Detecting, by the clock detection module, a time that the user's finger is held in the boot area when receiving the digital level signal output by the infrared sensing module;

When the distance control value is received by the power-on control module, and the time that the user's finger is held in the power-on area is greater than the preset time, the mobile terminal is controlled to enter a power-on state.

Preferably, after the output distance value, and before the receiving, by the clock detection module, the digital level signal output by the infrared sensing module, the method further includes: receiving, by the infrared temperature detecting module, the output of the infrared sensing module The digital level signal detects the temperature of the user's finger.

Preferably, the infrared temperature detecting module detects the temperature of the user's finger when receiving the digital level signal output by the infrared sensing module, including:

The infrared energy focusing unit detects the infrared energy radiated by the user's finger when receiving the high level output by the infrared sensing module;

Converting the infrared energy into a voltage signal by a voltage conversion unit;

The voltage signal is converted to temperature by a temperature conversion unit and output to the power-on control module.

Preferably, when the time value is received by the power-on control module, and the time that the user's finger is held in the power-on area is greater than the preset time, controlling the mobile terminal to enter the power-on state, the method further includes: determining, by the power-on control module Whether the temperature of the user's finger is within a preset temperature range, and whether the distance between the user's finger and the booting area is less than a preset distance, and if so, when the user's finger is held in the booting area for a longer time than the first preset When the time is up, the mobile terminal is controlled to be powered on normally; if not, when the time that the user's finger is kept in the booting area is greater than the second preset time, the mobile terminal is controlled to be powered on.

Preferably, the clock detection module detects the time that the user's finger is held in the boot area when receiving the digital level signal output by the infrared sensing module, including:

The clock detecting unit outputs a clock pulse signal when receiving the low level output by the infrared sensing module;

The duration of the high level of the clock signal is recorded by the clock counting unit and output to the power-on control module.

Preferably, before the outputting the digital level signal, when the infrared sensing module detects that the user's finger is located in the booting area of the mobile terminal, the method further includes:

When the air pressure sensor module senses that the air pressure in the power-on area changes, the air pressure change in the power-on area is converted into a weak voltage signal, and is output to the voltage amplifier module;

The weak voltage signal is amplified by the voltage amplifier module, and then filtered by the voltage stabilization filter module to output a stable voltage to the infrared sensing module. The invention also provides a smart terminal intelligent booting system, which comprises:

The infrared sensing module is configured to output a digital level signal when detecting that the user's finger is located in the booting area of the mobile terminal;

An infrared ranging module is configured to detect a distance between a user's finger and the booting area, and output a distance value;

a clock detection module, configured to detect a time that the user's finger is held in the boot area when receiving the digital level signal output by the infrared sensing module;

The power-on control module is configured to control the mobile terminal to enter a power-on state when the distance value is received, and the time that the user's finger is held in the power-on area is greater than a preset time.

Preferably, the method further includes: an infrared temperature detecting module, configured to detect a temperature of the user's finger when receiving the digital level signal output by the infrared sensing module.

In the smart terminal booting system of the mobile terminal, the infrared temperature detecting module includes:

An infrared energy focusing unit configured to detect infrared energy radiated by a user's finger when receiving a high level output by the infrared sensing module;

a voltage conversion unit for converting the infrared energy into a voltage signal;

And a temperature conversion unit configured to convert the voltage signal into a temperature and output to the power-on control module.

Preferably, the boot control module is further configured to: determine whether the temperature of the user's finger is within a preset temperature range, and whether the distance between the user's finger and the booting area is less than a preset distance; if yes, when the user's finger is Controlling the mobile terminal to be normally turned on when the time held in the booting area is greater than the first preset time; if not, controlling the mobile terminal to force when the time held by the user's finger in the booting area is greater than the second preset time Boot up.

Preferably, the clock detection module includes:

a clock detecting unit, configured to output a clock pulse signal when receiving a low level output by the infrared sensing module;

a clock counting unit for recording a duration of a high level of the clock signal.

Preferably, the method further includes:

The air pressure sensing module is configured to convert the air pressure change in the booting area into a weak voltage signal when the air pressure of the booting area is sensed, and output the signal to the voltage amplifier module;

a voltage amplifier module, configured to amplify the weak voltage signal, and output the amplified weak voltage signal to a voltage stabilization filter module;

The voltage stabilization filter module is configured to filter the amplified weak voltage signal and output a stable voltage to the infrared sensing module.

Beneficial effect

Compared with the prior art, the smart terminal intelligent booting system and the method thereof provide the digital terminal outputting the digital level through the infrared sensing module when detecting that the user's finger is located in the booting area of the mobile terminal. a signal; the distance between the user's finger and the booting area is detected by the infrared ranging module, and the distance value is output; after receiving the digital level signal output by the infrared sensing module, the clock detecting module detects that the user's finger is in the The time that is maintained in the boot area; after the time value is received by the power-on control module, and the time that the user's finger is held in the boot area is greater than the preset time, the mobile terminal is controlled to enter the power-on state, by detecting the user's finger and The distance between the boot areas of the mobile terminal and the time held by the user's finger in the boot area control the mobile terminal to be turned on, without using the button to boot, thereby improving the life of the power button of the mobile terminal, and bringing a brand new boot for the consumer. Experience.

DRAWINGS

FIG. 1 is a flowchart of a smart booting method of a mobile terminal provided by the present invention.

FIG. 2 is a flowchart of a smart booting method of a mobile terminal according to a preferred embodiment of the present invention.

FIG. 3 is a structural block diagram of a smart booting system for a mobile terminal provided by the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

In view of the shortcomings of the booting method in the prior art, the object of the present invention is to provide a smart booting system and method thereof, which can detect the distance between the user's finger and the booting area of the mobile terminal and the user's finger. The time kept in the boot area is controlled, and the mobile terminal is controlled to be powered on, without using a button to boot, thereby improving the life of the power button of the mobile terminal, and bringing a brand new boot experience to the consumer.

The present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to FIG. 1 , a smart booting method for a mobile terminal provided by the present invention includes the following steps:

S100. When the infrared sensing module detects that the user's finger is located in a booting area of the mobile terminal, outputting a digital level signal;

S200: The distance between the user's finger and the booting area is detected by the infrared ranging module, and the distance value is output;

S300. The clock detection module detects a time that the user's finger is held in the boot area when receiving the digital level signal output by the infrared sensing module.

S400: When the distance control value is received by the power-on control module, and the time that the user's finger is held in the power-on area is greater than the preset time, the mobile terminal is controlled to enter a power-on state.

In a specific implementation, a booting area is set on the screen of the mobile terminal. Before step S100, the air pressure sensing module senses the air pressure change of the booting area. When the user shakes the mobile phone, the air pressure sensing module will be in the booting area. The air pressure change is converted into a weak voltage signal and output to the voltage amplifier module. The weak voltage signal is amplified to 3V by a voltage amplifier module, and then filtered by the voltage regulator filter module to output a stable voltage to the infrared sensing module, which is an infrared sensor. The module provides a stable operating voltage of 3V.

The invention outputs a digital level signal when detecting that the user's finger is located in the booting area of the mobile terminal by the infrared sensing module, and the distance between the user's finger and the booting area is detected by the infrared ranging module, and the distance value is output, and then When the clock detection module receives the digital level signal output by the infrared sensing module, detecting the time that the user's finger is held in the booting area, when the power-on control module receives the distance value, and the user's finger is in the booting area When the held time is greater than the preset time, the mobile terminal is controlled to enter a power-on state, so that the mobile terminal can be controlled to boot by detecting the distance between the user's finger and the booting area of the mobile terminal and the time that the user's finger is held in the booting area. The state, without the user to use the physical button, or touch the screen can be turned on, bringing a new boot experience for consumers.

Further, referring to FIG. 2, in the preferred embodiment of the present invention, after the step S200, before the step S300, the method further includes the step S210, the digital level output by the infrared temperature detecting module is received by the infrared sensing module. When the signal is detected, the temperature of the user's finger is detected, and the temperature of the user's finger is detected in real time by the infrared temperature detecting module, so that the state of the user's finger in the booting area can be further determined, and the comprehensiveness of the booting detection is improved.

Further, the step S210 includes: detecting, by the infrared energy focusing unit, the infrared energy radiated by the user's finger when receiving the high level output by the infrared sensing module; converting the infrared energy into a voltage signal by the voltage converting unit; The temperature conversion unit converts the voltage signal into temperature and outputs it to the power-on control module.

In the preferred embodiment of the present invention, when the infrared sensing module detects that the user's finger is located in the booting area of the mobile terminal, the high-level signal is output to the infrared energy focusing unit, and the infrared energy of the user's finger is radiated by the infrared energy focusing unit. Gathering, then converting the infrared energy into a voltage signal through a voltage conversion unit, and converting the voltage signal into temperature by the temperature conversion unit, thereby real-time detecting the user's finger when detecting that the user's finger is located in the booting area The temperature provides a reliable basis for the startup control process.

Specifically, the step S300 includes: outputting, by the clock detecting unit, a clock pulse signal when receiving the low level output by the infrared sensing module; recording, by the clock counting unit, the duration of the high level of the clock signal, and outputting To the boot control module.

When the infrared sensing module detects that the user's finger is located in the booting area of the mobile terminal, it outputs a low level signal to the clock detecting unit, and the clock detecting unit outputs a clock pulse signal to the clock counting unit, and the clock counting unit records the clock pulse. The duration of the high level of the signal is output to the power-on control module, thereby detecting the time that the user's finger is held in the boot area, and the power-on control module receives the distance value output by the infrared ranging module, and the user's finger When the time kept in the booting area is greater than the preset time, the mobile terminal is controlled to enter the power-on state, and the user can start the booting without using the physical button, thereby greatly improving the life of the power button of the mobile terminal, and providing diversification for the consumer. Boot option.

In a specific implementation, the step S400 further includes: determining, by the booting control module, whether the temperature of the user's finger is within a preset temperature range, and whether the distance between the user's finger and the booting area is less than a preset distance, and if so, when When the time that the user's finger is held in the booting area is greater than the first preset time, the mobile terminal is controlled to be normally turned on; if not, when the time that the user's finger is held in the booting area is greater than the second preset time, the control is performed. The mobile terminal is forced to boot.

When the infrared ranging module detects the distance between the user's finger and the booting area and outputs the distance value, the infrared temperature detecting module detects the temperature of the user's finger, and the clock detecting module detects the time that the user's finger remains in the booting area. Afterwards, the boot control module determines whether the temperature of the user's finger is within a preset temperature range, and whether the distance between the user's finger and the boot area is less than a preset distance. If the preset temperature range is set to [36 ° C, 37 ° C], the preset distance is set to 7 cm.

When it is detected that the temperature of the user's finger is greater than or equal to 36 ° C, less than or equal to 37 ° C, and the distance between the user's finger and the booting area is less than 7 cm, for example, the temperature of the user's finger is 36.5 ° C, which is between the booting area and the booting area. When the distance is 3 cm, when the time that the user's finger is held in the booting area is greater than the first preset time, the booting control module controls the mobile terminal to be normally turned on, and the first preset time can be set to 5s, reducing the mobile terminal. Boot time, improve boot efficiency.

When it is detected that the temperature of the user's finger is greater than or equal to 36 ° C and less than or equal to 37 ° C, but the distance between the user's finger and the booting area is greater than or equal to 7 cm, for example, the temperature of the user's finger is 36.5 ° C, which is between the booting area and the booting area. The distance of the user is 10 cm, when the time that the user's finger is held in the booting area is greater than the second preset time, the power-on control module controls the mobile terminal to be powered on, and the second preset time can be set to 10s to extend Boot time, during which the user can further determine whether booting is required.

When it is detected that the distance between the user's finger and the booting area is less than 7 cm, but it is less than 36 ° C or greater than 37 ° C, for example, the distance between the user's finger and the booting area is 3 cm, and the temperature is 35.5 ° C or 37.5. °C, when the time that the user's finger is held in the booting area is greater than the second preset time, the power-on control module controls the mobile terminal to be powered on, and the second preset time may be set to 10s to extend the booting time. During this process, the user can further determine whether it is necessary to boot.

Of course, the preset temperature range, the preset distance, the first preset time, and the second preset time may be changed according to actual needs to meet the needs of different situations, which is not limited by the present invention.

The present invention further provides a smart terminal intelligent booting system, as shown in FIG. 3, the mobile terminal intelligent booting system includes an infrared sensing module 10, an air pressure sensing module 101, a voltage amplifier module 102, a voltage stabilizing filter module 103, The infrared ranging module 20, the clock detecting module 30 and the boot control module 40. The air pressure sensing module 101, the voltage amplifier module 102 and the voltage stabilizing filter module 103 are connected in sequence; the voltage stabilizing filter module 103 is connected to the infrared sensing module 10, and the infrared sensing module 10 is detected by the clock. The module 30 is connected to the boot control module 40, and the boot control module 40 is further connected to the infrared ranging module 20.

The infrared sensing module 10 is configured to output a digital level signal when detecting that the user's finger is located in the booting area of the mobile terminal.

The infrared ranging module 20 is configured to detect a distance between a user's finger and the booting area and output a distance value.

The clock detection module 30 is configured to detect a time that the user's finger is held in the boot area when receiving the digital level signal output by the infrared sensing module 10.

The power-on control module 40 is configured to control the mobile terminal to enter a power-on state when the distance value is received and the time that the user's finger is held in the power-on area is greater than a preset time.

In a specific implementation, a booting area is set on the screen of the mobile terminal, and the air pressure sensing module 101 senses a change in air pressure in the booting area. When the user shakes the mobile phone, the air pressure sensing module 101 turns on the booting area. The change of the air pressure inside is converted into a weak voltage signal and output to the voltage amplifier module 102, and the weak voltage signal is amplified to 3V by the voltage amplifier mode, and then filtered by the voltage stabilization filter module 103 to output a stable voltage to The infrared sensing module 10 provides the infrared sensing module 10 with a stable operating voltage of 3V.

The infrared sensing module 10 outputs a digital level signal when detecting that the user's finger is located in the booting area of the mobile terminal, and the infrared ranging module 20 detects the distance between the user's finger and the booting area at this time. And outputting the distance value, and then detecting the time that the user's finger is held in the booting area when the clock detecting module 30 receives the digital level signal output by the infrared sensing module 10, when the booting control module 40 receives the a distance value, and when the time that the user's finger is held in the booting area is greater than the preset time, the mobile terminal is controlled to enter a power-on state, thereby being able to detect the distance between the user's finger and the booting area of the mobile terminal and the user's finger in the The time kept in the boot area controls the mobile terminal to enter the power-on state, without the user using the physical button, or touching the screen to boot, bringing a brand new boot experience for the consumer.

Further, the smart terminal intelligent booting system provided by the present invention further includes an infrared temperature detecting module 50. The infrared temperature detecting module 50 is connected to the infrared sensing module 10 and the power-on control module 40.

The infrared temperature detecting module 50 is configured to detect the temperature of the user's finger when receiving the digital level signal output by the infrared sensing module 10, and detect the temperature of the user's finger in real time through the infrared temperature detecting module 50, which may further Determining the state of the user's finger in the boot area improves the comprehensiveness of the boot detection.

Further, the infrared temperature detecting module 50 includes an infrared energy focusing unit 501, a voltage converting unit 502, and a temperature converting unit 503. The infrared energy focusing unit 501, the voltage converting unit 502 and the temperature converting unit 503 are sequentially connected, the infrared energy focusing unit 501 is connected to the infrared sensing module 10, and the temperature converting unit 503 is connected to the powering control. Module 40.

The infrared energy focusing unit 501 is configured to detect infrared energy radiated by a user's finger when receiving the high level output by the infrared sensing module 10; the voltage converting unit 502 is configured to convert the infrared energy The voltage conversion unit 503 is configured to convert the voltage signal into temperature and output to the power-on control module 40.

When the infrared sensing module 10 detects that the user's finger is located in the booting area of the mobile terminal, it outputs a high level signal to the infrared energy focusing unit 501, and the infrared energy focusing unit 501 aggregates the infrared energy radiated by the user's finger. Then, the infrared energy is converted into a voltage signal by the voltage conversion unit 502, and the voltage signal is converted into temperature by the temperature conversion unit 503, thereby realizing that when the user's finger is detected in the booting area, Real-time detection of the temperature of the user's finger provides a reliable basis for the startup control process.

Referring to FIG. 3, the clock detection module 30 includes a clock detection unit 301 and a clock counting unit 302. The clock detecting unit 301 is connected to the infrared sensing module 10 and the clock counting unit 302, and the clock counting unit 302 is further connected to the booting control module 40. The clock detecting unit 301 is configured to output a clock pulse signal when receiving the low level output by the infrared sensing module 10; the clock counting unit 302 is configured to record the duration of the high level of the clock pulse signal.

When the infrared sensing module 10 detects that the user's finger is located in the booting area of the mobile terminal, it outputs a low level signal to the clock detecting unit 301, and the clock detecting unit 301 outputs a clock pulse signal to the clock counting unit 302. Recording, by the clock counting unit 302, the duration of the high level of the clock signal, and outputting to the power-on control module 40, thereby realizing detecting the time that the user's finger is held in the booting area, When the power-on control module 40 receives the distance value output by the infrared ranging module 20, and the time that the user's finger keeps in the power-on area is greater than the preset time, the mobile terminal is controlled to enter the power-on state, and the user does not need to use the physical button. It can realize the booting, greatly improving the life of the power button of the mobile terminal, and providing consumers with a variety of boot options.

In a specific implementation, the power-on control module 40 is further configured to determine whether the temperature of the user's finger is within a preset temperature range, and whether the distance between the user's finger and the booting area is less than a preset distance, and if so, when the user's finger Controlling the mobile terminal to be normally turned on when the time held in the booting area is greater than the first preset time; if not, controlling the mobile terminal when the time held by the user's finger in the booting area is greater than the second preset time Forced to boot.

When the infrared ranging module 20 detects the distance between the user's finger and the booting area and outputs a distance value, the infrared temperature detecting module 50 detects the temperature of the user's finger, and the clock detecting module 30 detects the user's finger. After the time held in the boot area, the boot control module 40 determines whether the temperature of the user's finger is within a preset temperature range, and whether the distance between the user's finger and the boot area is less than a preset distance. If the preset temperature range is set to [36 ° C, 37 ° C], the preset distance is set to 7 cm.

When it is detected that the temperature of the user's finger is greater than or equal to 36 ° C, less than or equal to 37 ° C, and the distance between the user's finger and the booting area is less than 7 cm, for example, the temperature of the user's finger is 36.5 ° C, which is between the booting area and the booting area. The distance is 3 cm, and when the time that the user's finger is held in the booting area is greater than the first preset time, the booting control module 40 controls the mobile terminal to be normally turned on, and the first preset time may be set to 5s. Reduce the time for the mobile terminal to boot and improve the boot efficiency. Of course, the preset temperature range, the preset distance, the first preset time, and the second preset time may be changed according to actual needs to meet the needs of different situations, which is not limited by the present invention. Other specific embodiments are described in detail in the foregoing specific embodiments of the smart terminal smart booting method, and are not described in detail herein.

In summary, the smart terminal intelligent booting system and the method thereof provide the digital terminal signal output by the infrared sensing module when the user's finger is located in the booting area of the mobile terminal; The infrared ranging module detects a distance between the user's finger and the booting area and outputs a distance value; after receiving the digital level signal output by the infrared sensing module, the clock detecting module detects that the user's finger remains in the booting area. After the time is received by the power-on control module, and the time that the user's finger is held in the power-on area is greater than the preset time, the mobile terminal is controlled to enter the power-on state, and the user's finger and the mobile terminal are detected. The distance between the boot areas and the time that the user's finger stays in the boot area controls the mobile terminal to boot up, and does not need to use the button to boot, thereby improving the life of the power button of the mobile terminal, and bringing a brand new boot experience to the consumer.

It is to be understood that those skilled in the art can make equivalent substitutions or changes to the inventions and the inventions of the present invention, and all such changes or substitutions fall within the scope of the appended claims.

Claims (17)

 A smart terminal smart booting method includes the following steps: When the infrared sensing module detects that the user's finger is located in the booting area of the mobile terminal, outputting a digital level signal; The distance between the user's finger and the booting area is detected by the infrared ranging module, and the distance value is output; When the digital detection signal output by the infrared sensing module is received by the clock detecting module, detecting the time that the user's finger is held in the booting area; Receiving the distance value and the holding time by the power-on control module, when the distance between the user finger and the booting area is less than a preset distance, and the time that the user's finger remains in the booting area is greater than the pre- When the time is set, the mobile terminal is controlled to enter a power on state. The smart terminal smart booting method according to claim 1, wherein after the outputting the distance value, and before the receiving, by the clock detecting module, the digital level signal output by the infrared sensing module, the method further comprises the step of: infrared The temperature detecting module detects the temperature of the user's finger when receiving the digital level signal output by the infrared sensing module. The method for intelligently booting a mobile terminal according to claim 2, wherein the detecting, by the infrared temperature detecting module, the temperature of the user's finger when receiving the digital level signal output by the infrared sensing module comprises: The infrared energy focusing unit detects the infrared energy radiated by the user's finger when receiving the high level output by the infrared sensing module; Converting the infrared energy into a voltage signal by a voltage conversion unit; The voltage signal is converted to temperature by a temperature conversion unit and output to the power-on control module. The smart terminal smart booting method according to claim 1, wherein the clock detecting module detects the time that the user's finger is held in the booting area when receiving the digital level signal output by the infrared sensing module, including: The clock detecting unit outputs a clock pulse signal when receiving the low level output by the infrared sensing module; The duration of the high level of the clock signal is recorded by the clock counting unit and output to the power-on control module. The smart terminal smart booting method according to claim 1, wherein before the infrared sensing module detects that the user's finger is located in the booting region of the mobile terminal, before outputting the digital level signal, the method further includes: When the air pressure sensor module senses that the air pressure in the power-on area changes, the air pressure change in the power-on area is converted into a weak voltage signal, and is output to the voltage amplifier module; The weak voltage signal is amplified by the voltage amplifier module, and then filtered by the voltage stabilization filter module to output a stable voltage to the infrared sensing module. A smart terminal smart booting method includes the following steps: When the infrared sensing module detects that the user's finger is located in the booting area of the mobile terminal, outputting a digital level signal; The distance between the user's finger and the booting area is detected by the infrared ranging module, and the distance value is output; When the digital detection signal output by the infrared sensing module is received by the clock detecting module, detecting the time that the user's finger is held in the booting area; When the distance control value is received by the power-on control module, and the time that the user's finger is held in the power-on area is greater than the preset time, the mobile terminal is controlled to enter a power-on state. The smart terminal smart booting method according to claim 6, wherein after the outputting the distance value, and before the receiving, by the clock detecting module, the digital level signal output by the infrared sensing module, the method further comprises the step of: infrared The temperature detecting module detects the temperature of the user's finger when receiving the digital level signal output by the infrared sensing module. The smart terminal smart booting method according to claim 7, wherein the infrared temperature detecting module detects the temperature of the user's finger when receiving the digital level signal output by the infrared sensing module, including: The infrared energy focusing unit detects the infrared energy radiated by the user's finger when receiving the high level output by the infrared sensing module; Converting the infrared energy into a voltage signal by a voltage conversion unit; The voltage signal is converted to temperature by a temperature conversion unit and output to the power-on control module. The smart terminal smart booting method according to claim 7, wherein the booting control module controls the mobile terminal to enter when the distance value is received and the user's finger is held in the booting area for a time greater than a preset time. The power-on state further includes: determining, by the power-on control module, whether the temperature of the user's finger is within a preset temperature range, and whether the distance between the user's finger and the booting area is less than a preset distance; if yes, when the user's finger is in the When the time in the boot area is greater than the first preset time, the mobile terminal is normally powered on; if not, the mobile terminal is forced to boot when the time that the user's finger is held in the boot area is greater than the second preset time. The smart terminal intelligent booting method according to claim 6, wherein the clock detecting module detects the time that the user's finger is held in the booting area when receiving the digital level signal output by the infrared sensing module, including: The clock detecting unit outputs a clock pulse signal when receiving the low level output by the infrared sensing module; The duration of the high level of the clock signal is recorded by the clock counting unit and output to the power-on control module. The smart terminal smart booting method according to claim 6, wherein before the infrared sensing module detects that the user's finger is located in the booting region of the mobile terminal, before outputting the digital level signal, the method further includes: When the air pressure sensor module senses that the air pressure in the power-on area changes, the air pressure change in the power-on area is converted into a weak voltage signal, and is output to the voltage amplifier module; The weak voltage signal is amplified by the voltage amplifier module, and then filtered by the voltage stabilization filter module to output a stable voltage to the infrared sensing module. A smart terminal intelligent booting system, comprising: The infrared sensing module is configured to output a digital level signal when detecting that the user's finger is located in the booting area of the mobile terminal; An infrared ranging module is configured to detect a distance between a user's finger and the booting area, and output a distance value; a clock detection module, configured to detect a time that the user's finger is held in the boot area when receiving the digital level signal output by the infrared sensing module; The power-on control module is configured to control the mobile terminal to enter a power-on state when the distance value is received, and the time that the user's finger is held in the power-on area is greater than a preset time. The smart terminal intelligent booting system of claim 12, further comprising: an infrared temperature detecting module, configured to detect a temperature of the user's finger when receiving the digital level signal output by the infrared sensing module. The smart terminal intelligent booting system according to claim 13, wherein the infrared temperature detecting module comprises: An infrared energy focusing unit is configured to detect infrared energy radiated by a user's finger when receiving a high level output by the infrared sensing module; a voltage conversion unit for converting the infrared energy into a voltage signal; And a temperature conversion unit configured to convert the voltage signal into a temperature and output to the power-on control module. The smart terminal booting system of claim 14, wherein the booting control module is further configured to: determine whether the temperature of the user's finger is within a preset temperature range, and whether the distance between the user's finger and the booting area is less than a preset distance; if yes, when the time that the user's finger is held in the booting area is greater than the first preset time, the mobile terminal is normally powered on; if not, the time that the user's finger is held in the booting area is greater than At the second preset time, the mobile terminal is controlled to be powered on. The smart terminal booting system of claim 12, wherein the clock detecting module comprises: a clock detecting unit, configured to output a clock pulse signal when receiving a low level output by the infrared sensing module; a clock counting unit for recording a duration of a high level of the clock signal. The intelligent booting system for a mobile terminal according to claim 12, further comprising: The air pressure sensing module is configured to convert the air pressure change in the booting area into a weak voltage signal when the air pressure of the booting area is sensed, and output the signal to the voltage amplifier module; a voltage amplifier module, configured to amplify the weak voltage signal, and output the amplified weak voltage signal to a voltage stabilization filter module; The voltage stabilization filter module is configured to filter the amplified weak voltage signal and output a stable voltage to the infrared sensing module.