CN107980125B - Temperature monitoring method and device and user equipment - Google Patents

Abstract

A temperature monitoring method, a temperature monitoring device (400) and a user equipment (600) comprising: a step (101) of waking up the user equipment (600) according to a preset regular interval in a sleep mode of the user equipment (600); a step (102) of acquiring the body temperature of the user equipment (600) at each wake-up; and triggering the user equipment (600) to control the temperature prompt module (403) to send out a temperature change prompt according to the change trend of the body temperature (103). The method can realize monitoring and reminding of the temperature state of the user equipment (600) during sleep.

Description

Temperature monitoring method and device and user equipment

Technical Field

The invention relates to the technical field of equipment state monitoring, in particular to a temperature monitoring method and device and user equipment.

Background

For user equipment such as desktop computers and notebook computers, the whole computer generates heat seriously due to the existence of high-speed operation chips such as CPU and GPU. For this case, the user equipment is mostly equipped with a heat dissipating device, such as a heat dissipating fan, a heat sink, and the like. However, the built-in heat dissipation device may not meet the requirement of real-time heat dissipation of the user equipment. At present, in order to prevent components in the user equipment from being damaged by high temperature, after the user equipment runs for a period of time, the user needs to manually sleep or shut down the user equipment to dissipate heat. When the user equipment is in a dormant state, the CPU stops running and cannot control the user equipment to inform the user of the current temperature state, so that the user needs to sense the current temperature state by touching the machine body, and further, whether the machine can be started again for running is judged. Obviously, the method for sensing the temperature state of the user equipment through the touch machine body is complex to operate, inaccurate in feedback effect and not beneficial to improving user experience.

Disclosure of Invention

In view of the above problems in the prior art, embodiments of the present invention provide a temperature monitoring method, an apparatus, and a user equipment, so as to implement temperature monitoring and reminding of the user equipment in a sleep state, and improve user experience.

A method of temperature monitoring, comprising:

in a sleep mode of user equipment, awakening the user equipment according to a preset regular interval;

acquiring the body temperature of the user equipment at each awakening;

and triggering the user equipment to control the temperature prompt module to send a temperature change prompt according to the change trend of the body temperature.

A temperature monitoring device comprising:

the device awakening unit is used for awakening the user equipment according to a preset regular interval in a sleep mode of the user equipment;

the temperature acquisition unit is used for acquiring the body temperature of the user equipment during awakening each time;

and the temperature prompting unit is used for triggering the user equipment to control the temperature prompting module to send out a temperature change prompt according to the change trend of the body temperature.

A user device comprises a processor, a temperature sensor and a temperature prompt module, wherein the processor is electrically connected with the temperature sensor and the temperature prompt module;

the processor is used for awakening the user equipment according to a preset regular interval in a sleep mode of the user equipment;

the temperature sensor is used for collecting the body temperature of the user equipment when the user equipment is awakened every time;

the processor is further used for controlling the temperature prompt module to send out a temperature change prompt according to the change trend of the temperature of the machine body.

The temperature monitoring method comprises the steps of awakening the user equipment according to preset regular intervals, collecting the body temperature of the user equipment when awakening every time, triggering the user equipment to control the temperature prompt module to send a temperature change prompt according to the change trend of the body temperature, and enabling the temperature reduction prompt sent by the prompt module to change along with the change trend of the body temperature, so that a user can conveniently know the current temperature state of the user equipment according to the change of the temperature reduction prompt, the temperature monitoring and reminding of the user equipment in a dormant state are achieved, and the user experience is improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below.

FIG. 1 is a first flowchart of a temperature monitoring method according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a heat dissipation curve of a user equipment at normal temperature in a temperature monitoring method according to an embodiment of the present invention;

FIG. 3 is a second schematic flow chart of a temperature monitoring method provided by an embodiment of the invention;

FIG. 4 is a schematic diagram of a first structure of a temperature monitoring device provided by an embodiment of the invention;

FIG. 5 is a schematic diagram of a second structure of a temperature monitoring device according to an embodiment of the present invention;

fig. 6 is a schematic diagram of a first structure of a user equipment according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a temperature prompt module of a user equipment according to an embodiment of the present invention;

fig. 8 is a second structural diagram of a user equipment according to an embodiment of the present invention;

fig. 9 is a schematic structural diagram of a comparator of a user equipment according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, in an embodiment of the present invention, a temperature monitoring method is provided, which is applied to a user equipment with a large heating value to implement temperature monitoring and reminding of the user equipment in a sleep state. The temperature monitoring method at least comprises the following steps:

step 101: in the sleep mode of the user equipment, awakening the user equipment according to a preset regular interval;

step 102: acquiring the body temperature of user equipment during each awakening;

step 103: and triggering the user equipment to control the temperature prompt module to send a temperature change prompt according to the change trend of the temperature of the machine body.

The user equipment is awakened at intervals, the temperature of the machine body is collected when the user equipment is awakened at every time, the change trend of the temperature of the machine body can be determined according to the temperature of the machine body collected when the user equipment is awakened at present and the temperature of the machine body collected when the user equipment is awakened at the previous time, and after the change trend of the temperature of the machine body is obtained, the temperature change reminding can be sent according to the change trend. For example, the variation trend of the fuselage temperature can be gradually reduced, gradually increased or kept unchanged. In the embodiment of the present invention, a heat dissipation situation of the user equipment in a room temperature environment after the user equipment is in a sleep state is taken as an example to describe the temperature monitoring method provided by the embodiment of the present invention.

The user device may be, but is not limited to, a desktop computer, a notebook computer, and the like. When the user equipment is in operation, the whole machine generates heat seriously due to the existence of high-speed operation chips such as a CPU (central processing unit), a GPU (graphics processing unit) and the like. In order to prevent components in the user equipment from being damaged by high temperature, the user needs to manually sleep or shut down the user equipment to dissipate heat after the user equipment runs for a period of time. The heat dissipation curve of the user equipment at normal temperature is shown in fig. 2. As can be seen from the trend of the heat dissipation curve in fig. 2, the higher the body temperature of the user equipment is, the larger the temperature drop amplitude in unit time is, and as the body temperature gradually approaches to the normal temperature (e.g., room temperature), the heat dissipation curve tends to be gentle, that is, the temperature drop amplitude in unit time gradually decreases. Therefore, according to the size of the body temperature drop amplitude in unit time, the size of the current body temperature can be judged: the larger the temperature drop amplitude of the machine body in unit time is, the higher the current machine body temperature is, and the smaller the temperature drop amplitude of the machine body in unit time is, the lower the current machine body temperature is.

In this embodiment, for realizing the temperature monitoring of the user equipment in the sleep mode, the user equipment is awakened according to the preset regular interval, and when awakening at every time, the body temperature of the user equipment is collected, and then the size of the descending amplitude of the body temperature collected by awakening for two adjacent times is calculated, and the size of the descending amplitude of the former time is combined, the variation trend of the descending amplitude of the body temperature is judged, and then according to the variation trend of the descending amplitude of the body temperature, the user equipment is triggered to control the temperature prompt module to send a temperature descending prompt, so that the user can conveniently learn the temperature state of the user equipment through the temperature descending prompt when the equipment is in the sleep state.

It will be appreciated that in one embodiment, the user equipment may be woken up according to a preset fixed wake-up frequency interval. Specifically, the fixed wake-up frequency of the user equipment can be preset through application software on the user equipment, the processor of the user equipment is waken up according to the fixed wake-up frequency interval, the body temperature of the user equipment is collected through a temperature sensor connected with the processor when the user equipment is wakened up every time, the body temperature is compared with the body temperature collected when the user equipment is wakened up last time, the falling amplitude of the body temperature is calculated, and the temperature state of the user equipment is judged according to the size of the falling amplitude of the body temperature. Meanwhile, the processor controls the temperature prompt module connected with the processor to send out a temperature reduction prompt, for example, the flicker frequency of the LED is controlled to be gradually reduced along with the reduction of the temperature reduction amplitude of the machine body.

Referring to fig. 3, in an embodiment, waking up the ue at a preset regular interval includes:

step 301: acquiring the body temperature of the user equipment at intervals according to a preset temperature acquisition frequency;

step 302: comparing whether the difference between the two adjacent collected airframe temperatures exceeds a preset threshold value;

step 303: and if the difference of the body temperatures exceeds a preset threshold value, awakening the user equipment.

In this embodiment, a hardware comparator may be disposed between the temperature sensor and the processor of the user equipment, and the hardware comparator reads the body temperature of the user equipment acquired by the temperature sensor according to a preset temperature acquisition frequency interval, and compares whether a difference between two adjacent acquired body temperatures exceeds a preset threshold, and if so, wakes up the user equipment. Specifically, the body temperature of the user equipment may be collected before the user equipment enters the sleep mode, and the body temperature may be used as the reference temperature. After entering the sleep mode, the hardware comparator reads the temperature of the machine body collected by the temperature sensor according to a preset frequency interval for a certain time, compares the currently collected temperature of the machine body with a reference temperature (namely, the temperature of the machine body collected before entering the sleep mode), wakes up the user equipment if the difference between the two collected temperatures of the machine body exceeds a preset threshold value, and takes the currently collected temperature of the machine body as a new reference temperature for comparison with the temperature of the machine body collected next time.

It can be understood that if the difference between the airframe temperatures does not exceed the preset threshold, the airframe temperature acquired for the first time in the two adjacent acquisitions is taken as the reference temperature; comparing whether the difference between the reference temperature and the next acquired temperature of the fuselage after the two adjacent acquisitions exceeds a preset threshold value or not; and if the difference between the reference temperature and the next acquired body temperature after the two adjacent acquisitions exceeds a preset threshold value, awakening the user equipment. For example, if the difference between the first acquired body temperature and the reference temperature after entering the sleep mode exceeds a preset threshold, the user equipment is awakened, and the first acquired body temperature after entering the sleep mode is used as a new reference temperature, and if the difference between the second acquired body temperature after entering the sleep mode and the first acquired body temperature does not exceed the preset threshold, the user equipment is not awakened after the second acquisition is completed. Meanwhile, the first collected body temperature is continuously used as a reference temperature, the third collected body temperature is compared with the first collected body temperature after a certain time interval, and if the difference between the third collected body temperature and the first collected body temperature exceeds a preset threshold value, the user equipment is awakened.

It can be understood that the heat dissipation curve of the user equipment gradually tends to be gentle along with the reduction of the body temperature, so that the temperature reduction range in unit time is gradually reduced, the user equipment is awakened only when the body temperature difference acquired twice exceeds the preset threshold value by setting the preset threshold value, the awakening frequency of the user equipment is gradually reduced along with the reduction of the body temperature, and the reduction of the power consumption of the user equipment is facilitated.

In one embodiment, according to the variation trend of the temperature of the body, triggering the user equipment to control the temperature prompting module to send a temperature variation prompt includes:

comparing the change amplitude of the temperature of the machine body of two adjacent wake-up intervals;

if the variation amplitude of the body temperature is gradually reduced, triggering the user equipment to control the temperature prompt module to gradually change the temperature reduction prompt;

if the variation amplitude of the temperature of the machine body is not changed, comparing the sizes of two adjacent awakening intervals, wherein the time difference between two adjacent awakening intervals corresponds to one awakening interval;

and if the wake-up interval is gradually increased, triggering the user equipment to control the temperature prompt module to gradually change the temperature reduction prompt.

The temperature prompt module may be, but is not limited to, an LED module, an audio prompt module, and the like, and accordingly, the temperature drop prompt may be, but is not limited to, a gradually decreasing LED flashing frequency, an audio prompt message with gradually increasing intervals, and the like. For example, when the temperature of the body of the user equipment is high, the LED flickers at a high frequency, and as the temperature of the body gradually decreases, the flickering frequency of the LED also gradually decreases.

According to the trend of a heat dissipation curve of the user equipment, if the user equipment is awakened at a fixed frequency and the body temperature of the user equipment is collected, the falling amplitude of the body temperature in unit time is gradually reduced along with the advance of time, and accordingly, the user equipment can be triggered to control the temperature prompt module to change the temperature falling prompt, for example, the flashing frequency of an LED is reduced when the user equipment is awakened each time. If the user equipment is awakened according to the difference between the fixed body temperatures as the preset threshold, the descending range of the body temperature may be unchanged in two adjacent awakening intervals, but according to the trend of the heat dissipation curve of the user equipment, the time required for the same temperature descending range is longer along with the descending of the body temperature, namely, the awakening interval of the user equipment is gradually increased. Therefore, by comparing the sizes of two adjacent wake-up intervals, if the wake-up intervals are gradually increased, the user equipment is triggered to control the temperature prompt module to gradually change the temperature drop prompt.

In one embodiment, according to the variation trend of the temperature of the body, triggering the user equipment to control the temperature prompting module to send a temperature variation prompt includes:

calculating the variation amplitude of the temperature of the fuselage acquired twice;

inquiring a preset temperature prompt parameter table, and acquiring a temperature change prompt control parameter corresponding to the change amplitude of the body temperature; the preset temperature prompt parameter table is used for establishing a mapping relation between different variation amplitudes of the body temperature and corresponding temperature variation prompt control parameters;

and triggering the user equipment to control the temperature prompt module to send out a corresponding temperature change prompt according to the temperature change prompt control parameter.

Specifically, taking the heat dissipation situation of the user equipment in the room temperature environment after the user equipment is in the sleep state as an example, according to the heat dissipation curve in the room temperature environment, the higher the body temperature of the user equipment is, the larger the temperature drop amplitude in the unit time is, and as the body temperature gradually approaches the room temperature, the heat dissipation curve tends to be gentle, that is, the temperature drop amplitude in the unit time gradually decreases. Therefore, under the condition that the awakening interval is fixed, the corresponding temperature change prompt control parameters can be obtained by inquiring the preset temperature prompt parameter table according to the size of the descending amplitude of the body temperature collected twice and by presetting the mapping relation table (namely the preset temperature prompt parameter table) between the descending amplitude of the body temperature and the corresponding temperature change prompt control parameters, and then the user equipment is triggered to control the temperature prompt module to send the corresponding temperature change prompt according to the temperature change prompt control parameters.

It can be understood that if the user equipment is awakened according to whether the difference between the body temperatures exceeds the preset threshold, the awakening interval corresponding to the same body temperature difference gradually increases as the body temperature gradually approaches the room temperature. Therefore, the awakening interval can be added into a mapping relation table between the preset falling range of the body temperature and the corresponding temperature change prompt control parameter as a reference item. When the temperature drop amplitude of the machine body is unchanged, the awakening interval in the preset temperature prompt parameter table is inquired, and then the corresponding temperature change prompt control parameter is obtained according to the awakening interval, and then the user equipment is triggered to control the temperature prompt module to send out the corresponding temperature change prompt according to the temperature change prompt control parameter.

Referring to fig. 4, in an embodiment of the invention, a temperature monitoring device 400 is provided, which includes:

an apparatus wake-up unit 401, configured to wake up the ue according to a preset regular interval in a sleep mode of the ue;

a temperature acquisition unit 402, configured to acquire a body temperature of the user equipment at each wake-up;

and the temperature prompting unit 403 is configured to trigger the user equipment to control the temperature prompting module to send a temperature change prompt according to a change trend of the body temperature.

In an embodiment, the device wake-up unit 401 is further configured to wake up the ue according to a preset fixed wake-up frequency interval.

Referring to fig. 5, in one embodiment, a temperature monitoring device 400' is provided, which further includes a temperature comparing unit 405, compared to the temperature monitoring device 400 shown in fig. 4;

the temperature acquisition unit 402 is further configured to acquire the body temperature of the user equipment at intervals according to a preset temperature acquisition frequency;

a temperature comparison unit 405, configured to compare whether a difference between two adjacent acquired airframe temperatures exceeds a preset threshold;

the device wake-up unit 401 is further configured to wake up the user device when the difference between the body temperatures exceeds a preset threshold.

In one embodiment, the temperature comparison unit 405 is further configured to:

when the difference of the body temperatures does not exceed a preset threshold value, taking the body temperature acquired for the first time in two adjacent acquisitions as a reference temperature; and are

Comparing whether the difference between the reference temperature and the next acquired temperature of the fuselage after the two adjacent acquisitions exceeds a preset threshold value or not;

and the equipment awakening unit is also used for awakening the user equipment when the difference between the reference temperature and the next acquired body temperature after the two adjacent acquisitions exceeds a preset threshold value.

In one embodiment, the temperature prompting unit 404 is further configured to:

comparing the change amplitude of the temperature of the machine body of two adjacent wake-up intervals;

when the variation amplitude of the body temperature is gradually reduced, triggering the user equipment to control the temperature prompt module to gradually change the temperature change prompt;

when the variation amplitude of the temperature of the machine body is unchanged, comparing the sizes of two adjacent awakening intervals, wherein the time difference between two adjacent awakening intervals corresponds to one awakening interval;

and when the wake-up interval is gradually increased, triggering the user equipment to control the temperature prompt module to gradually change the temperature change prompt.

In one embodiment, the temperature prompting unit 404 is further configured to:

calculating the variation amplitude of the temperature of the fuselage acquired twice;

inquiring a preset temperature prompt parameter table, and acquiring a temperature change prompt control parameter corresponding to the change amplitude of the body temperature; the preset temperature prompt parameter table is used for establishing a mapping relation between different variation amplitudes of the body temperature and corresponding temperature variation prompt control parameters;

and triggering the user equipment to control the temperature prompt module to send out a corresponding temperature change prompt according to the temperature change prompt control parameter.

It is understood that the functions and specific implementations of the components of the temperature monitoring devices 400 and 400' can also refer to the descriptions related to the method embodiments shown in fig. 1 to 3, and are not described herein again.

Referring to fig. 6, in an embodiment of the present invention, a user equipment 600 is provided, which includes a processor 601, a temperature sensor 602, and a temperature prompt module 603, where the processor is electrically connected to the temperature sensor and the temperature prompt module;

a processor 601, configured to wake up a ue according to a preset regular interval in a sleep mode of the ue;

a temperature sensor 602, configured to collect a body temperature of the user equipment at each wake-up;

the processor 601 is further configured to control the temperature prompt module 603 to send a temperature change prompt according to a variation trend of the body temperature.

In one embodiment, the processor 601 is further configured to wake up the ue according to a preset fixed wake-up frequency interval.

It is to be understood that, in an embodiment, before entering the sleep mode, the fixed wake-up frequency may be set by a management application installed on the user equipment 600, or alternatively, a management application for the user equipment 600 may be installed on a mobile terminal such as a mobile phone, and then a communication connection between the mobile terminal and the user equipment 600 is established through communication methods such as Wi-Fi and bluetooth, and the fixed wake-up frequency is set by the management application on the mobile terminal. It will be appreciated that the fixed wake-up frequency may be set according to actual needs, e.g. 5 seconds, 30 seconds, 1 minute, etc.

Referring to fig. 7, in an embodiment, the temperature prompting module 603 may include an operational amplifier U1, a resistor R1, R2, R3 and R4, a capacitor C1 and a light emitting diode LED, the operational amplifier U1 includes a first input terminal 11, a second input terminal 12 and an output terminal 13, the first input terminal 11 is connected to a digital-to-analog conversion GPIO (general purpose input/output) pin of the processor 601 and is grounded through a resistor R3, the resistor R2 is connected between the first input terminal 11 and the output terminal 13, the output terminal 13 is further connected to one ends of a resistor R1 and a resistor R4, the other end of the resistor R1 is grounded through a capacitor C1, the other end of the resistor R4 is connected to an anode of the LED, a cathode of the LED is grounded, and the second input terminal 12 is connected to a common connection point of the resistor R1 and the capacitor C1.

It can be understood that when the processor 601 can read the airframe temperature collected by the temperature sensor 602 according to the fixed wake-up frequency interval, and calculate the falling amplitude of the airframe temperature collected by two adjacent wake-ups; and according to the change of the descending amplitude of the temperature of the body, different voltage values are output through the GPIO pins for digital-to-analog conversion to control the light emitting state of the LED. For example, when the digital-to-analog conversion GPIO output voltage of the processor 601 is higher than a first voltage threshold, the LED is controlled to be normally on, when the digital-to-analog conversion GPIO output voltage of the processor 601 is lower than a second voltage threshold, the LED is controlled to be turned off, when the digital-to-analog conversion GPIO output voltage of the processor 601 is higher than or equal to the second voltage threshold and lower than or equal to the first voltage threshold, the LED is controlled to flicker and emit light, and the flicker frequency of the LED can be changed along with the change of the output voltage, for example, when the falling amplitude of the fuselage temperature gradually decreases, the changed voltage can be output through the digital-to-analog conversion GPIO of the processor 601 to control the flicker frequency. The first voltage threshold and the second voltage threshold can be set according to temperature monitoring requirements.

Referring to fig. 8, in an embodiment, a user equipment 600' is provided, which is opposite to the user equipment 600 shown in fig. 6, and further includes a comparator 604 electrically connected to the processor 601; the temperature sensor 602 is also electrically connected to the comparator 604.

The temperature sensor 602 is further configured to acquire the body temperature of the user equipment at intervals according to a preset temperature acquisition frequency;

a comparator 604, configured to compare whether a difference between two adjacent acquired airframe temperatures exceeds a preset threshold;

the processor 601 is further configured to wake up the user equipment when the difference between the body temperatures exceeds a preset threshold.

Referring to fig. 9, in an embodiment, the comparator 604 may include a first input terminal 21, a second input terminal 22 and an output terminal 23, the first input terminal 21 is connected to a digital-to-analog conversion GPIO of the processor 601 for inputting a reference temperature, the second input terminal 22 is connected to the temperature sensor 602 for reading the body temperature of the user equipment acquired by the temperature sensor 602 at intervals according to a preset temperature acquisition frequency, and comparing the read body temperature with the reference temperature, and if a difference between the reference temperature and the body temperature is greater than a preset threshold, outputting a wake-up signal to the initialization pin INT GPIO of the processor 601 through the output terminal 23, thereby waking up the user equipment 600. It is understood that the body temperature of the user equipment 600 may be collected and used as the reference temperature before the user equipment enters the sleep mode. After entering the sleep mode, the comparator 604 reads the body temperature collected by the temperature sensor 602 at a certain time interval according to a preset frequency, compares the currently collected body temperature with a reference temperature, wakes up the user equipment 600 if the difference between the currently collected body temperature and the reference temperature exceeds a preset threshold, and takes the currently collected body temperature as a new reference temperature for comparison with the body temperature collected next time.

It can be understood that if the difference between the airframe temperatures does not exceed the preset threshold, the airframe temperature acquired for the first time in the two adjacent acquisitions is taken as the reference temperature; comparing whether the difference between the reference temperature and the next acquired temperature after two adjacent acquisitions exceeds a preset threshold value through a comparator 604; the processor 601 is further configured to wake up the user equipment 600 when a difference between the reference temperature and the next acquired body temperature after two adjacent acquisitions exceeds a preset threshold.

In one embodiment, the processor 601 is further configured to:

comparing the change amplitude of the temperature of the machine body of two adjacent wake-up intervals;

when the variation range of the body temperature gradually decreases, the temperature prompt module 603 is controlled to gradually change the temperature reduction prompt;

when the change of the temperature of the machine body is not changed in amplitude reduction, comparing the sizes of two adjacent awakening intervals, wherein the time difference between two adjacent awakening intervals corresponds to one awakening interval;

the temperature prompt module 603 is controlled to gradually change the temperature decrease prompt at increasing wake-up intervals.

In one embodiment, the processor 601 is further configured to:

calculating the variation amplitude of the temperature of the fuselage acquired twice;

inquiring a preset temperature prompt parameter table, and acquiring a temperature change prompt control parameter corresponding to the change amplitude of the body temperature; the preset temperature prompt parameter table is used for establishing a mapping relation between different variation amplitudes of the body temperature and corresponding temperature variation prompt control parameters;

and triggering the user equipment to control the temperature prompt module to send out a corresponding temperature change prompt according to the temperature change prompt control parameter.

It is understood that the functions of the components of the user equipment 600, 600' and their specific implementations may also refer to the related descriptions in the method embodiments shown in fig. 1 to fig. 3, and are not described herein again.

The temperature monitoring method wakes up the user equipment according to the preset regular intervals, collects the body temperature of the user equipment every time of waking up, and then triggers the user equipment to control the temperature prompt module to send the temperature change prompt according to the change trend of the body temperature.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention.

Claims (15)

1. A method of monitoring temperature, comprising:

in a sleep mode of user equipment, awakening the user equipment according to a preset regular interval;

acquiring the body temperature of the user equipment at each awakening;

according to the trend of change of fuselage temperature, trigger user equipment control temperature suggestion module sends the temperature change suggestion, specifically includes:

comparing the change amplitude of the temperature of the machine body of two adjacent wake-up intervals;

if the variation amplitude of the body temperature gradually becomes smaller, triggering the user equipment to control the temperature prompt module to gradually change the temperature change prompt;

if the variation amplitude of the temperature of the machine body is not changed, comparing the sizes of two adjacent awakening intervals, wherein the time difference between two adjacent awakening intervals corresponds to one awakening interval;

and if the awakening interval is gradually increased, triggering the user equipment to control the temperature prompt module to gradually change the temperature change prompt.

2. The method for monitoring temperature according to claim 1, wherein the waking up the UE at the preset regular interval comprises:

and awakening the user equipment according to a preset fixed awakening frequency interval.

3. The method for monitoring temperature according to claim 1, wherein the waking up the UE at the preset regular interval comprises:

acquiring the body temperature of the user equipment at intervals according to a preset temperature acquisition frequency;

comparing whether the difference between the two adjacent collected airframe temperatures exceeds a preset threshold value;

and if the difference of the body temperatures exceeds the preset threshold value, awakening the user equipment.

4. The method for monitoring temperature according to claim 3, wherein the waking up the UE according to the preset regular interval further comprises:

if the difference of the airframe temperatures does not exceed the preset threshold, taking the airframe temperature acquired for the first time in the two adjacent acquisitions as a reference temperature;

comparing whether the difference between the reference temperature and the next acquired body temperature after the two adjacent acquisitions exceeds a preset threshold value or not;

and if the difference between the reference temperature and the next acquired body temperature after the two adjacent acquisitions exceeds the preset threshold value, awakening the user equipment.

5. The temperature monitoring method according to any one of claims 1 to 4, wherein the triggering the user equipment to control the temperature prompting module to send out the temperature change prompt according to the variation trend of the body temperature comprises:

calculating the variation amplitude of the temperature of the fuselage acquired twice;

inquiring a preset temperature prompt parameter table, and acquiring a temperature change prompt control parameter corresponding to the change amplitude of the body temperature; the preset temperature prompt parameter table is used for establishing a mapping relation between different variation amplitudes of the body temperature and corresponding temperature variation prompt control parameters;

and triggering the user equipment to control the temperature prompt module to send out a corresponding temperature change prompt according to the temperature change prompt control parameter.

6. A temperature monitoring device, comprising:

the device awakening unit is used for awakening the user equipment according to a preset regular interval in a sleep mode of the user equipment;

the temperature acquisition unit is used for acquiring the body temperature of the user equipment during awakening each time;

the temperature prompting unit is used for triggering the user equipment control temperature prompting module to send a temperature change prompt according to the change trend of the body temperature, and is also used for:

comparing the change amplitude of the temperature of the machine body of two adjacent wake-up intervals;

when the variation amplitude of the body temperature is gradually reduced, triggering the user equipment to control the temperature prompt module to gradually change the temperature change prompt;

when the variation amplitude of the temperature of the machine body is unchanged, comparing the sizes of two adjacent awakening intervals, wherein the time difference between two adjacent awakening intervals corresponds to one awakening interval;

and when the awakening interval is gradually increased, triggering the user equipment to control the temperature prompt module to gradually change the temperature change prompt.

7. The temperature monitoring device according to claim 6, wherein the device wake-up unit is further configured to wake-up the UE according to a preset fixed wake-up frequency interval.

8. The temperature monitoring device of claim 6, further comprising a temperature comparison unit;

the temperature acquisition unit is also used for acquiring the body temperature of the user equipment at intervals according to a preset temperature acquisition frequency;

the temperature comparison unit is used for comparing whether the difference between the two adjacent collected airframe temperatures exceeds a preset threshold value or not;

the device awakening unit is further used for awakening the user device when the difference of the body temperatures exceeds the preset threshold value.

9. The temperature monitoring device of claim 8, wherein the temperature comparison unit is further configured to:

when the difference of the airframe temperatures does not exceed the preset threshold value, the airframe temperature acquired for the first time in the two adjacent acquisitions is used as a reference temperature; and are

Comparing whether the difference between the reference temperature and the next acquired body temperature after the two adjacent acquisitions exceeds a preset threshold value or not;

the device awakening unit is further used for awakening the user device when the difference between the reference temperature and the next acquired body temperature after the two adjacent acquisitions exceeds the preset threshold value.

10. The temperature monitoring device according to any one of claims 6-9, wherein the temperature prompting unit is further configured to:

calculating the variation amplitude of the temperature of the fuselage acquired twice;

inquiring a preset temperature prompt parameter table, and acquiring a temperature change prompt control parameter corresponding to the change amplitude of the body temperature; the preset temperature prompt parameter table is used for establishing a mapping relation between different variation amplitudes of the body temperature and corresponding temperature variation prompt control parameters;

and triggering the user equipment to control the temperature prompt module to send out a corresponding temperature change prompt according to the temperature change prompt control parameter.

11. The user equipment is characterized by comprising a processor, a temperature sensor and a temperature prompt module, wherein the processor is electrically connected with the temperature sensor and the temperature prompt module;

the processor is used for awakening the user equipment according to a preset regular interval in a sleep mode of the user equipment;

the temperature sensor is used for collecting the body temperature of the user equipment when the user equipment is awakened every time;

the processor is further used for controlling the temperature prompt module to send out a temperature change prompt according to the change trend of the temperature of the machine body, and is further used for:

comparing the change amplitude of the temperature of the machine body of two adjacent wake-up intervals;

when the variation amplitude of the temperature of the machine body is gradually reduced, controlling the temperature prompting module to gradually change the temperature variation prompt;

when the variation amplitude of the temperature of the machine body is unchanged, comparing the sizes of two adjacent awakening intervals, wherein the time difference between two adjacent awakening intervals corresponds to one awakening interval;

and when the awakening interval is gradually increased, controlling the temperature prompting module to gradually change the temperature change prompt.

12. The UE of claim 11, wherein the processor is further configured to wake up the UE according to a preset fixed wake-up frequency interval.

13. The user equipment of claim 11, further comprising a comparator electrically connected to the processor;

the temperature sensor is also used for acquiring the body temperature of the user equipment at intervals according to a preset temperature acquisition frequency;

the comparator is used for comparing whether the difference between the two adjacent collected airframe temperatures exceeds a preset threshold value or not;

the processor is further configured to wake up the user equipment when the difference between the body temperatures exceeds the preset threshold.

14. The user equipment of claim 13, wherein the comparator is further configured to:

when the difference of the airframe temperatures does not exceed the preset threshold value, the airframe temperature acquired for the first time in the two adjacent acquisitions is used as a reference temperature; and are

Comparing whether the difference between the reference temperature and the next acquired body temperature after the two adjacent acquisitions exceeds a preset threshold value or not;

the processor is further configured to wake up the user equipment when a difference between the reference temperature and the next acquired body temperature after the two adjacent acquisitions exceeds the preset threshold.

15. The user equipment of any of claims 11-14, wherein the processor is further configured to:

calculating the variation amplitude of the temperature of the fuselage acquired twice;

inquiring a preset temperature prompt parameter table, and acquiring a temperature change prompt control parameter corresponding to the change amplitude of the body temperature; the preset temperature prompt parameter table is used for establishing a mapping relation between different variation amplitudes of the body temperature and corresponding temperature variation prompt control parameters;

and triggering the user equipment to control the temperature prompt module to send out a corresponding temperature change prompt according to the temperature change prompt control parameter.

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