CN115944278A

CN115944278A - Body temperature detection method, earphone device and computer readable storage medium

Info

Publication number: CN115944278A
Application number: CN202310010249.XA
Authority: CN
Inventors: 李佳男; 陈星百; 史洲源; 李亚静; 史长元
Original assignee: Goertek Inc
Current assignee: Goertek Inc
Priority date: 2023-01-04
Filing date: 2023-01-04
Publication date: 2023-04-11
Anticipated expiration: 2043-01-04
Also published as: CN115944278B

Abstract

The invention discloses a body temperature detection method, earphone equipment and a computer readable storage medium, wherein the body temperature detection method is applied to the earphone equipment and used for acquiring temperature data acquired by each temperature sensor; determining a body temperature state according to the temperature data and a preset body temperature threshold interval; and if the body temperature state is an abnormal state, outputting body temperature abnormal prompt information. The invention realizes the real-time detection of the body temperature of the human body.

Description

Body temperature detection method, earphone device and computer readable storage medium

Technical Field

The present invention relates to the field of earphone technologies, and in particular, to a body temperature detection method, an earphone device, and a computer-readable storage medium.

Background

In recent years, identification of a patient with fever through body temperature measurement is one of the main detection means at present. The conventional body temperature detection needs special instruments such as a thermometer, a thermometer and the like, but the instruments are not frequently used, the body temperature detection instrument can be actively used for measuring the body temperature only when a patient shows physical symptoms, if diseases with infectious properties cannot be found in time, serious consequences are brought to the patient and a contactee, and therefore, how to carry out the body temperature detection in real time becomes important.

Disclosure of Invention

The invention mainly aims to provide a body temperature detection method, earphone equipment and a computer readable storage medium, and aims to provide a body temperature detection scheme to realize real-time detection of the body temperature of a human body.

In order to achieve the above object, the present invention provides a body temperature detecting method applied to an earphone device, wherein the earphone device is provided with a temperature sensor, and the body temperature detecting method comprises:

acquiring temperature data acquired by each temperature sensor;

determining a body temperature state according to the temperature data and a preset body temperature threshold interval;

and if the body temperature state is an abnormal state, outputting body temperature abnormal prompt information.

Optionally, the temperature sensor includes a first temperature sensor and a second temperature sensor respectively disposed on a first earphone and a second earphone of the earphone device, and the step of determining the body temperature state according to the temperature data and a preset body temperature threshold interval includes:

respectively acquiring a first temperature acquired by the first temperature sensor and a second temperature acquired by the second temperature sensor;

and calculating the average value of the first temperature and the second temperature to be used as the actual body temperature, and comparing the actual body temperature with the body temperature threshold interval to determine the body temperature state.

Optionally, the temperature sensors include a third temperature sensor and a fourth temperature sensor that are disposed in different location areas of any one of the earphones, and the step of determining the body temperature state according to the temperature data and a preset body temperature threshold interval further includes:

respectively acquiring the environment temperature acquired by the third temperature sensor and the human body temperature acquired by the fourth temperature sensor;

determining a compensation value of the human body temperature according to a preset body temperature compensation rule and the environment temperature;

and compensating the human body temperature according to the compensation value to obtain an actual body temperature, and comparing the actual body temperature with the body temperature threshold interval to determine the body temperature state.

Optionally, the step of determining the body temperature state according to the temperature data and a preset body temperature threshold interval includes:

comparing the temperature data to the body temperature threshold interval;

if the temperature data is within the body temperature threshold range, judging that the body temperature state is a normal state;

if the temperature data is smaller than the minimum value of the body temperature threshold interval, judging that the body temperature state is a suspected low-temperature abnormal state, and accumulating one to low-temperature times corresponding to the suspected low-temperature abnormal state;

if the temperature data is larger than the maximum value of the body temperature threshold interval, judging that the body temperature state is a suspected high-temperature abnormal state, and accumulating one to high-temperature times corresponding to the suspected high-temperature abnormal state;

and acquiring new low temperature times and/or new high temperature times, evaluating the suspected low-temperature abnormal state and/or the suspected high-temperature abnormal state according to the new low temperature times and/or the new high temperature times, and determining an effective abnormal state as the body temperature state.

Optionally, the step of evaluating the suspected low-temperature abnormal state and/or the suspected high-temperature abnormal state according to the new low-temperature frequency and/or the new high-temperature frequency, and determining an effective abnormal state as the body temperature state includes:

if the new low temperature times are larger than a preset first threshold, determining that the suspected low temperature abnormal state is a valid abnormal state, and determining that the body temperature state is a low temperature abnormal state;

if the new high temperature times is larger than the first threshold, determining that the suspected high temperature abnormal state is a valid abnormal state, and determining that the body temperature state is a high temperature abnormal state;

and if the new low-temperature times and/or the new high-temperature times are smaller than or equal to the first threshold, returning to the step of acquiring the temperature data acquired by each temperature sensor.

Optionally, after the step of determining that the body temperature state is a normal state, the method further includes:

and clearing the low-temperature times and the high-temperature times, acquiring temperature data transmitted by the temperature sensor at intervals of a preset first time length, and returning to execute the step of determining the body temperature state according to the temperature data and a preset body temperature threshold interval.

Optionally, the abnormal state includes a low-temperature abnormal state and a high-temperature abnormal state, and if the body temperature state is the abnormal state, the step of outputting the body temperature abnormal prompt information includes:

if the body temperature state is a low-temperature abnormal state, sending preset low-temperature abnormal prompt information to a user terminal associated with the earphone equipment, and controlling the earphone equipment to play a preset low-temperature abnormal prompt tone;

and if the body temperature state is a high-temperature abnormal state, sending preset high-temperature abnormal prompt information to a user terminal associated with the earphone equipment, and controlling the earphone equipment to play a preset high-temperature abnormal prompt tone.

Optionally, the step of acquiring the temperature data collected by each of the temperature sensors includes:

when the earphone device is detected to be started in a body temperature detection mode, acquiring temperature data acquired by each temperature sensor;

the body temperature detection method further comprises the following steps:

and if the earphone equipment is detected to be in an unworn state and/or a dormant state, closing the body temperature detection mode of the earphone equipment.

To achieve the above object, the present invention also provides an earphone device, including: the body temperature detection method comprises a memory, a processor and a body temperature detection program which is stored on the memory and can run on the processor, wherein the steps of the body temperature detection method are realized when the body temperature detection program is executed by the processor.

In addition, in order to achieve the above object, the present invention further provides a computer readable storage medium, on which a body temperature detecting program is stored, and the body temperature detecting program implements the steps of the body temperature detecting method when executed by a processor.

In the invention, the real-time acquisition of the body temperature of the human body is realized by acquiring the temperature data acquired by each temperature sensor; further determining the body temperature state according to the temperature data and a preset body temperature threshold interval; further, if the body temperature state is abnormal, body temperature abnormal prompt information is output to realize real-time detection of the body temperature state of the user, the abnormal body temperature state of the human body is found in time, and the user is reminded to perform corresponding treatment and seek medical advice in time; the earphone device convenient to carry is used for detecting the body temperature of a human body in real time, so that the earphone device is convenient for people to use daily, has higher practicability, and further protects the health of a user and improves the timeliness and the practicability of the body temperature detection method by accurately judging and timely reminding the abnormal body temperature state.

Drawings

FIG. 1 is a schematic flow chart of a body temperature detecting method according to a first embodiment of the present invention;

fig. 2 is a schematic diagram of a body temperature detection module of an earphone device according to an embodiment of the present invention;

FIG. 3 is a schematic flow chart illustrating a body temperature detecting method according to a second embodiment of the present invention;

FIG. 4 is a schematic flow chart of a body temperature detecting method according to a third embodiment of the present invention;

fig. 5 is a schematic flow chart of a body temperature detecting method according to a fourth embodiment of the invention.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and do not limit the invention.

Referring to fig. 1, fig. 1 is a schematic flow chart of a body temperature detecting method according to a first embodiment of the present invention.

While a logical order is shown in the flow chart, in some cases, the steps shown or described may be performed in an order different than presented herein. The body temperature detection method provided by the embodiment of the invention is applied to earphone equipment. In this embodiment, the body temperature detection method includes:

step S10, acquiring temperature data acquired by each temperature sensor;

in this embodiment, the earphone device may be a Wireless earphone, a wired earphone, or the like, and exemplarily, the earphone device is a TWS (True Wireless Stereo) bluetooth earphone; the earphone equipment is provided with temperature sensors in different position areas, and then temperature data collected and transmitted by the temperature sensors are obtained.

In a feasible implementation mode, the earphone device has a body temperature detection mode, and when the body temperature detection mode of the earphone is started, the temperature data collected and transmitted by the temperature sensor is obtained according to the preset second time length. The second time duration is the time duration for acquiring the temperature data acquired by each temperature sensor, and may be preset according to the big data statistical analysis result, or may be determined according to the actual situation, which is not limited in this embodiment; the temperature data refers to a temperature value acquired by the temperature sensor, and can be used for acquiring a temperature value at the next moment after waiting for the second duration, and also can be used for acquiring an average value of the temperature data dynamically acquired by the temperature sensor within the second duration.

The temperature sensor is a sensor which can sense temperature and convert the temperature into a usable output signal, and can be a contact temperature sensor or a non-contact temperature sensor.

In another possible implementation manner, referring to fig. 2, which is a schematic diagram of a body temperature detection module of an earphone device according to an embodiment of the present invention, the body temperature detection module includes a temperature sensor for acquiring a body temperature of a user and transmitting a corresponding electrical signal (temperature signal), and then transmits the electrical signal to a temperature signal conditioning circuit for signal amplification of the electrical signal (temperature signal), and then transmits the amplified telecommunication to an ADC conversion circuit for converting the electrical signal into a digital signal recognizable to a microprocessor of the earphone, and then converts the digital signal into a temperature value (temperature data) through processing by the microprocessor.

In another possible embodiment, the user may control to turn on the body temperature detection mode through a preset mode turning on mode, for example, the user may control to turn on the body temperature detection mode by touching or tapping a preset area of the earphone, or may control to turn on the body temperature detection mode by shielding a photosensitive sensor disposed in the earphone for a preset time, which is not limited in this embodiment.

Step S20, determining a body temperature state according to the temperature data and a preset body temperature threshold interval;

and comparing the obtained temperature data with a preset body temperature threshold interval to determine a body temperature state corresponding to the temperature data, namely the body temperature state of a user (an earphone wearer).

In one possible embodiment, the body temperature state includes a normal state and an abnormal state; the abnormal states include a high-temperature abnormal state and a low-temperature abnormal state, wherein the high-temperature abnormal state includes low fever, medium fever and high fever, and the low-temperature abnormal state includes mild low temperature, medium low temperature, deep low temperature and ultra-deep low temperature.

The preset body temperature threshold interval is a normal body temperature value interval of the human body, can be preset according to the big data statistical analysis result, and can also be determined according to the actual situation; for example, the preset body temperature threshold interval may be set according to an ambient temperature and/or a heart rate value of the user, and if the ambient temperature and/or the heart rate value of the user are higher, a maximum value of the corresponding preset body temperature threshold interval is increased; if the ambient temperature and/or the heart rate value of the user is lower, the minimum value of the corresponding preset body temperature threshold interval is reduced; the body temperature threshold interval can also be set according to the part corresponding to the human body temperature collected by the temperature sensor; for example, the body temperature threshold interval is the first body temperature interval if the temperature sensor collects the in-ear temperature, and the body temperature threshold interval is the second threshold interval if the temperature sensor collects the auricle temperature, which is not limited in this embodiment.

And step S30, if the body temperature state of the temperature data is abnormal, outputting body temperature abnormal prompt information.

And if the body temperature state is judged to be abnormal, outputting a corresponding body temperature abnormal signal to a reminding module of the earphone and a related user terminal according to the abnormal state so as to remind the user of the abnormal state of the body temperature at the moment and ensure the health of the user. And the reminding module of the earphone is used for flashing the corresponding indicator light according to the abnormal signal and playing the corresponding reminding sound.

In the embodiment, the real-time acquisition of the body temperature of the human body is realized by acquiring the temperature data acquired by each temperature sensor; further determining a body temperature state according to the temperature data and a preset body temperature threshold interval; if the body temperature state is abnormal, outputting body temperature abnormal prompt information to realize real-time detection of the body temperature state of the user, finding out the abnormal body temperature state of the human body in time, reminding the user to perform corresponding treatment and hospitalizing in time; the earphone device convenient to carry is used for detecting the body temperature of a human body in real time, so that the earphone device is convenient for people to use daily, has higher practicability, and further protects the health of a user and improves the timeliness and the practicability of a body temperature detection method by accurately judging and timely reminding the abnormal state of the body temperature.

Further, a second embodiment of the body temperature detecting method according to the present invention is proposed based on the first embodiment, and referring to fig. 3, in this embodiment, step S20 includes: :

step S201, respectively acquiring a first temperature acquired by a first temperature sensor and a second temperature acquired by a second temperature sensor;

in this embodiment, the temperature sensors include a first temperature sensor and a second temperature sensor respectively disposed on a first earphone and a second earphone of the earphone device, so as to respectively obtain a first temperature collected and transmitted by the first temperature sensor and a second temperature collected and transmitted by the second temperature sensor; the first temperature and the second temperature refer to an in-ear temperature or an external ear cavity temperature of the user collected by the first temperature sensor and the second temperature sensor.

Step S202, calculating an average value of the first temperature and the second temperature to serve as an actual body temperature, and comparing the actual body temperature with a body temperature threshold interval to determine a body temperature state.

And calculating the average temperature value of the first temperature and the second temperature according to the acquired first temperature and the second temperature to serve as the actual body temperature. Illustratively, the first temperature is a left ear in-ear temperature, the second temperature is a right ear in-ear temperature, and an average temperature value of the acquired left ear in-ear temperature and the acquired right ear in-ear temperature is calculated as the actual temperature.

In a feasible implementation mode, when a human body is in a low-temperature or high-temperature environment, the body temperature of the human body changes along with the environment temperature, and after the human body moves violently, the body temperature also changes along with the movement severity and the body state of the human body correspondingly, so that after the temperature data transmitted by the temperature sensor is obtained, the temperature data is compensated according to a preset body temperature compensation rule, so that the influence of other factors on the collected temperature data is eliminated, and the actual body temperature is further determined.

The preset compensation rule is a rule for performing corresponding temperature compensation on the acquired temperature data according to factors such as environment temperature, human body state, heart rate and the like; illustratively, when a user is in an environment with a high temperature, due to the influence of the ambient temperature on the human body, the acquired temperature data can be slightly increased compared with the temperature at normal temperature, so that the acquired temperature data is compensated according to a preset compensation rule to eliminate the increase of the temperature data caused by the ambient temperature, and further obtain the actual body temperature; the actual body temperature refers to the exact body temperature value of the wearer (user) of the headset.

In another possible implementation, calculating a temperature difference between the first temperature and the second temperature, and judging whether the temperature difference is greater than a preset binaural temperature difference threshold; if the temperature difference is less than or equal to the preset binaural temperature difference threshold, executing step S202; if the temperature difference is greater than a preset binaural temperature difference threshold, accumulating one for the binaural temperature difference abnormal times; further acquiring a new binaural temperature difference abnormal frequency, and if the new binaural temperature difference abnormal frequency is less than or equal to a preset first threshold, executing the step S10; if the new times of the abnormal temperature difference between the ears is larger than a preset first threshold value, outputting an abnormal temperature difference signal between the ears to remind a user that ear diseases such as otitis media and otitis externa possibly exist due to large temperature difference between the ears and please seek medical advice as soon as possible; the preset binaural temperature difference threshold refers to a critical value of a normal range of the binaural temperature difference between the ears of the same user.

In another possible implementation manner, the position information of a first earphone and a second earphone of the earphones is respectively obtained, and the wearing mode of the earphones is determined according to the position information, wherein the wearing mode comprises a single mode and a double mode; if the earphone is in a double mode, the first temperature and the second temperature are respectively used as the actual body temperature, and then the body temperature and the body temperature state of a first earphone wearer and a second earphone wearer are respectively determined; if the headset is in the single-person mode, step S202 is executed. The position information refers to the distance difference and the direction angle difference of the first earphone relative to the second earphone, and if the distance difference is not within a preset head circumference distance range or the direction angle difference is larger than a preset angle threshold value, the wearing mode of the earphones is determined to be a double mode; and if the distance difference is within the preset head circumference distance range and the direction angle difference is smaller than the preset angle threshold, determining that the wearing mode of the earphone is a single mode.

In this embodiment, through the first temperature that acquires first temperature sensor collection and the second temperature that second temperature sensor gathered respectively, and then calculate the average value of first temperature and second temperature in order to regard as actual body temperature to compare with actual body temperature and body temperature threshold interval in order to confirm the body temperature state, and then eliminate the influence of other factors to body temperature measuring result as far as possible, thereby make actual body temperature more be close to true body temperature, realize the accurate detection to human true body temperature.

Step S203, respectively acquiring the environment temperature acquired by the third temperature sensor and the human body temperature acquired by the fourth temperature sensor;

in this embodiment, the temperature sensors include a third temperature sensor and a fourth temperature sensor disposed in different position areas of any one of the earphones in the earphone device, where the third temperature sensor is configured to collect and transmit an ambient temperature, and the fourth temperature sensor is configured to collect and transmit a human body temperature. Illustratively, the third temperature sensor is arranged at one side of the sound hole of the earphone, which is close to the human body, so as to measure the temperature in the ear of the wearer of the earphone as the human body temperature; the fourth temperature sensor is arranged on one side, away from the human body, of the rear shell of the earphone so as to collect the ambient temperature; the third temperature sensor is arranged on one side, close to the human body, of the ear handle shell of the earphone so as to measure the temperature of the external ear pinna of a wearer of the earphone as the temperature of the human body.

Step S204, determining a compensation value of the human body temperature according to a preset body temperature compensation rule and the environmental temperature;

and determining a temperature influence value generated by the ambient temperature on the human body temperature according to a preset body temperature compensation rule and the ambient temperature, and further determining a compensation value according to the temperature influence value. The temperature influence value is a temperature value which can cause the temperature change of a human body under the current environment temperature; the compensation value is a temperature value which compensates for the influence of the environmental temperature on the human body temperature; illustratively, the preset body temperature compensation rule includes a compensation function or a compensation model related to the ambient temperature and the human body temperature variation, so that according to the preset body temperature compensation rule, an influence value of the ambient temperature on the measured human body temperature can be determined, and then a compensation value can be determined.

And S205, compensating the human body temperature according to the compensation value to obtain the actual body temperature, and comparing the actual body temperature with the body temperature threshold interval to determine the body temperature state.

And compensating the human body temperature according to the obtained compensation value, further obtaining the compensated human body temperature as an actual temperature, and comparing the actual body temperature with a body temperature threshold interval to determine the body temperature state.

In an embodiment, the compensated human body temperature includes a first human body temperature of a first earphone and a second human body temperature of a second earphone of the earphones, and an average value of the first human body temperature and the second human body temperature is calculated as the actual temperature.

In this embodiment, through the human temperature who acquires the ambient temperature that third temperature sensor gathered and the human temperature that fourth temperature sensor gathered respectively, and then confirm the offset value of human temperature according to preset body temperature compensation rule and ambient temperature, and then compensate in order to obtain actual body temperature according to the offset value to human temperature, and compare in order to confirm the body temperature state with actual body temperature and body temperature threshold interval, thereby eliminate the influence of other factors to body temperature measuring result as far as possible, thereby make actual body temperature more be close to true body temperature, the realization is to the accurate detection of human true body temperature.

Further, a third embodiment of the body temperature detecting method according to the present invention is proposed based on the first and/or second embodiment, and referring to fig. 4, in this embodiment, step S20 includes:

step S206, comparing the temperature data with a body temperature threshold interval;

the temperature data collected by the temperature sensor is compared with the temperature threshold interval to determine the relationship between the temperature data and the temperature sensor threshold, thereby determining the body temperature state.

In a feasible implementation mode, the temperature data acquired by the temperature sensor is compensated according to a preset body temperature compensation rule to serve as the actual body temperature, and then the actual body temperature is compared with the body temperature threshold interval, so that the accuracy of judging the body temperature state is improved.

Step S207, if the temperature data is in the body temperature threshold interval, determining that the body temperature state is a normal state;

and comparing the temperature data with a preset body temperature threshold interval, and if the temperature data is in the body temperature threshold interval and indicates that the temperature data is in a normal body temperature range of a human body, judging that the body temperature state of the user is a normal state. Illustratively, the body temperature threshold interval is 35.7-37.2 ℃, the temperature data is 37 ℃, and the body temperature state is determined to be a normal state within the body temperature threshold interval.

In a possible embodiment, after the step of determining the body temperature state as the normal state, the method further comprises:

and step S2071, clearing the low temperature times and the high temperature times, acquiring temperature data acquired by each temperature sensor according to a preset first time length, and returning to the step of determining the body temperature state according to the temperature data and a preset body temperature threshold interval.

If the body temperature state of the user is judged to be a normal state, the body temperature of the user is indicated to be normal, and the low-temperature times and the high-temperature times which are obtained before are cleared, so that the times of misjudgment caused by external factors are eliminated, and the accuracy of body temperature state judgment is improved; the temperature data transmitted by the temperature sensor is acquired according to a preset first time length as the body temperature of the human body changes slowly, wherein the first time length is longer than the acquisition time of the initial temperature data; exemplarily, when the earphone device starts a body temperature detection mode for the first time or determines that the body temperature state is a suspected abnormal state, the temperature data collected by each temperature sensor is obtained according to a preset second time length, wherein the first time length is longer than the second time length; (ii) a The first duration is a duration for acquiring temperature data transmitted by the temperature sensor, and may be preset according to a big data statistical analysis result, or may be determined according to an actual situation, which is not limited in this embodiment; the temperature data refers to temperature values acquired by the temperature sensor, and can be obtained at the current moment after every first time period, or can be obtained as an average value of the temperature data dynamically acquired by the temperature sensor within the first time period. After the body temperature state of the user is determined to be the normal state, the acquisition time of the temperature data is prolonged, so that the power consumption (energy conservation) of the earphone is saved, and the service life of the earphone is further prolonged.

Step S208, if the temperature data is less than the minimum value of the body temperature threshold interval, determining that the body temperature state is a suspected low-temperature abnormal state, and accumulating one for the low-temperature times corresponding to the suspected low-temperature abnormal state;

comparing the temperature data with a preset body temperature threshold interval, if the temperature data is smaller than the minimum value of the body temperature threshold interval, indicating that the temperature data is lower than the normal body temperature of a human body, and in order to avoid the conditions that the actual temperature obtained is lower and the like due to the misdetection of a temperature sensor or the attack of cold wind on the ear of a user, judging that the body temperature state of the user is a suspected low-temperature abnormal state, and accumulating one for low-temperature times corresponding to the suspected low-temperature abnormal state; the number of times of low temperature is the number of times of continuous determination of a suspected low-temperature abnormal state.

In a feasible real-time manner, if the temperature data is smaller than the minimum value of the body temperature threshold interval, then determining a low-temperature difference of the temperature data compared with the minimum value of the body temperature threshold interval, and then determining a specific suspected low-temperature abnormal state according to the low-temperature difference, wherein the suspected low-temperature abnormal state comprises: suspected mild hypothermia, suspected moderate hypothermia, suspected deep hypothermia, and suspected ultra deep hypothermia. Through the determination of the low-temperature difference, the body temperature state of the user is judged in more detail.

Step S209, if the temperature data is larger than the maximum value of the body temperature threshold interval, determining that the body temperature state is a suspected high-temperature abnormal state, and accumulating one for high-temperature times corresponding to the suspected high-temperature abnormal state;

comparing the temperature data with a preset body temperature threshold interval, if the temperature data is greater than the maximum value of the body temperature threshold interval, indicating that the temperature data is higher than the normal body temperature of a human body, and in order to avoid the situations that the actual temperature obtained is higher due to the misdetection of a temperature sensor or the blowing of hot air to the ear of a user and the like, judging that the body temperature state of the user is a suspected high-temperature abnormal state, and accumulating one for the high-temperature times corresponding to the suspected high-temperature abnormal state; the number of times of high temperature is the number of times of continuous determination of a suspected high-temperature abnormal state.

In a feasible real-time manner, if the temperature data is greater than the maximum value of the body temperature threshold interval, determining a high temperature difference between the temperature data and the maximum value of the body temperature threshold interval, and determining a specific suspected high temperature abnormal state according to the high temperature difference, wherein the suspected high temperature abnormal state includes: suspected low fever, suspected medium fever and suspected high fever. Through the determination of the high-temperature difference, the body temperature state of the user is judged in more detail.

Step S210, obtaining a new low temperature number and/or a new high temperature number, and evaluating the suspected low temperature abnormal state and/or the suspected high temperature abnormal state according to the new low temperature number and/or the new high temperature number, and determining an effective abnormal state as the body temperature state.

And after the body temperature state is determined, acquiring new low temperature times and/or new high temperature times, and evaluating the suspected low-temperature abnormal state and/or the suspected high-temperature abnormal state according to the new low temperature times and/or the new high temperature times so as to eliminate the influence of other factors on the judgment result, and further determining an effective abnormal state as the body temperature state according to the evaluation result.

In the embodiment, the body temperature state is determined by comparing the temperature data with a preset body temperature threshold interval; if the temperature data is within the body temperature threshold interval, judging that the body temperature state is a normal state; if the temperature data is smaller than the minimum value of the body temperature threshold interval, judging that the body temperature state is a suspected low-temperature abnormal state, and accumulating one for low-temperature times corresponding to the suspected low-temperature abnormal state; if the temperature data is larger than the maximum value of the body temperature threshold interval, judging that the body temperature state is a suspected high-temperature abnormal state, and accumulating one for high-temperature times corresponding to the suspected high-temperature abnormal state; in order to increase the accuracy of judging the body temperature state, a new low temperature frequency and/or a new high temperature frequency are further acquired, the suspected low temperature abnormal state and/or the suspected high temperature abnormal state are evaluated according to the new low temperature frequency and/or the new high temperature frequency, an effective abnormal state is determined to be the body temperature state, the determination of the continuous abnormal frequency is used as a secondary judgment, errors or errors caused by single temperature data judgment are reduced, and the accuracy of judging the body temperature state is further improved.

In a feasible real-time mode, the step of evaluating the suspected low-temperature abnormal state and/or the suspected high-temperature abnormal state according to the new low-temperature times and/or the new high-temperature times, and the step of determining the effective abnormal state as the body temperature state comprises the following steps:

step S2101, if the new low-temperature times are greater than a preset first threshold, determining that the suspected low-temperature abnormal state is an effective abnormal state, and determining that the body temperature state is a low-temperature abnormal state;

in order to evaluate the suspected abnormal state, the acquired new low-temperature times are compared with a preset first threshold, and if the new low-temperature times are larger than the preset first threshold, the fact that the body temperature state is judged to be the suspected low-temperature abnormal state continuously for multiple times is indicated, the suspected low-temperature abnormal state is determined to be an effective abnormal state, and then the body temperature state of the user is determined to be the low-temperature abnormal state.

The preset first threshold is a maximum critical value of the obtained consecutive times of the abnormal state, and may be preset according to a statistical analysis result of the big data, or may be determined according to an actual situation, which is not limited in this embodiment.

Step S2102, if the new high temperature times are larger than a first threshold value, determining that the suspected high temperature abnormal state is a valid abnormal state, and determining that the body temperature state is a high temperature abnormal state;

in order to evaluate the suspected abnormal state, the obtained new high-temperature times are compared with a preset first threshold, if the new high-temperature times are larger than the preset first threshold, the fact that the body temperature state is judged to be the suspected high-temperature abnormal state for multiple times is indicated, the suspected high-temperature abnormal state is determined to be an effective abnormal state, and then the body temperature state of the user is determined to be the high-temperature abnormal state.

Step S2103, if the new low temperature number and/or the new high temperature number is less than or equal to the first threshold, returning to the step of acquiring the temperature data acquired by each temperature sensor.

In order to evaluate the suspected abnormal state, the obtained new high temperature number is compared with a preset first threshold, if the new low temperature number and/or the new high temperature number are/is smaller than or equal to the first threshold, it indicates that the number of times of determining that the body temperature state is the suspected abnormal state is less, and in order to avoid misjudgment caused by other factors, the step S10 is executed to re-determine the body temperature state of the user.

In this embodiment, since the acquired temperature data may have an error with the actual human body temperature due to external factors, it is easy to misjudge the body temperature state, and in order to increase the accuracy of judging the body temperature state, a new low temperature number and/or a new high temperature number are further acquired, and then the suspected low temperature abnormal state and/or the suspected high temperature abnormal state are evaluated, and an effective abnormal state is determined as the body temperature state; if the new high-temperature times are larger than the first threshold value of the temperature data, determining that the suspected high-temperature abnormal state is a valid abnormal state, and judging that the body temperature state is a high-temperature abnormal state; if the new low temperature times is larger than the first threshold of the temperature data, determining that the suspected low temperature abnormal state is an effective abnormal state, and determining that the body temperature state is a low temperature abnormal state; if the new low temperature times and/or the new high temperature times are less than or equal to the first threshold of the temperature data, executing a step of acquiring the temperature data transmitted by the temperature sensor according to the first time length of the temperature data; by determining the continuous abnormal times as the secondary judgment, errors or errors caused by single temperature data judgment are reduced, and the accuracy of body temperature state judgment is further improved.

Further, a fourth embodiment of the body temperature detecting method according to the present invention is proposed based on the first, second and/or third embodiments, and referring to fig. 5, in this embodiment, the step S30 of outputting the body temperature abnormality prompting information if the body temperature state is an abnormal state includes:

step S301, if the body temperature state is a low-temperature abnormal state, sending a preset low-temperature abnormal prompt message to a user terminal associated with the earphone device, and controlling the earphone device to play a preset low-temperature abnormal prompt tone;

if the body temperature is judged to be abnormal, the body temperature of the user at the moment is low, and for the body state of the user, preset low-temperature abnormal prompt information is sent to a user terminal associated with the earphone, so that the user terminal displays the actual body temperature, the body temperature state, the body temperature change condition and/or low-temperature recommended measures of the user at the moment, and a reminding module of the earphone is controlled to play preset low-temperature abnormal prompt tones, flashing indicator lights and the like.

The user terminal may be an electronic device such as a personal computer and a smart phone connected to the earphone, which is not limited in this embodiment.

Step S302, if the body temperature state is a high temperature abnormal state, sending a preset high temperature abnormal prompt message to a user terminal associated with the earphone device, and controlling the earphone device to play a preset high temperature abnormal prompt tone.

If the body temperature state is judged to be the high-temperature abnormal state, the body temperature of the user at the moment is indicated to be high, and for the body state of the user, preset high-temperature abnormal prompt information is sent to a user terminal associated with the earphone, so that the user terminal displays the actual body temperature, the body temperature state, the body temperature change condition and/or high-temperature recommended measures of the user at the moment, and a reminding module of the earphone is controlled to play a preset high-temperature abnormal prompt tone, a flickering indicator light and the like.

In this embodiment, the corresponding body temperature abnormal prompt information is output according to the abnormal state to remind the user of the actual body temperature state, timely reminding of the user is realized through differentiated notification, and the nursing measures corresponding to the body temperature abnormal state of the user are given, so that the user is helped to make the body temperature abnormal state more clear, the user is guided to seek medical advice in time, further aggravation of the body temperature abnormal state is avoided, and timely reminding of the body temperature abnormal state and provision of a proper nursing scheme are realized.

Further, a fifth embodiment of the body temperature detecting method according to the present invention is proposed based on the first, second, third and/or fourth embodiments, and in this embodiment, the step S10 includes:

step S40, when the earphone device is detected to start the body temperature detection mode, acquiring temperature data collected by each temperature sensor;

the earphone equipment is provided with a body temperature detection mode, and when the earphone equipment is detected to start the body temperature detection mode, the temperature data collected by each temperature sensor is obtained.

In a feasible embodiment, the user may control to turn on the body temperature detection mode through a preset mode turning on mode, for example, the user may control to turn on the body temperature detection mode by tapping a preset area of the earphone, or may control to turn on the body temperature detection mode by shielding a photosensitive sensor provided in the earphone for a preset time, which is not limited in this embodiment.

The body temperature detection method further comprises the following steps:

and S50, if the earphone device is detected to be in an unworn state and/or a dormant state, closing the body temperature detection mode of the earphone device.

When the earphone is in the body temperature detection mode, if the wearing state of the earphone is detected to be switched to the non-wearing state and/or the earphone is in the dormant state, the user indicates that the body temperature detection function is temporarily stopped, and in order to save the power consumption of the earphone, the body temperature detection mode of the earphone is closed.

In a feasible real-time manner, the user may turn off the body temperature detection mode by taking off the first earphone and/or the second earphone worn, or may control to turn off the body temperature detection mode by touching or tapping a preset area of the earphone, or may control to turn off the body temperature detection mode by shielding a photosensitive sensor provided in the earphone for a preset time, which is not limited in this embodiment.

In this embodiment, the body temperature detection mode is automatically turned off by detecting the wearing state and the running state of the earphone, so that the power consumption of the earphone is saved, and the service life of the earphone is further prolonged.

The earphone device comprises a structural shell, a communication module, a main control module (such as a Micro Control Unit (MCU)), a loudspeaker, a microphone, a memory and the like. The earphone device is internally provided with at least one temperature sensor for collecting body temperature data (temperature data) of a user, and the main control module can comprise a microprocessor, an audio decoding unit, a power supply and power supply management unit, a temperature signal organizing circuit, an ADC (analog to digital converter) conversion circuit, a sensor required by the system, other active or passive devices and the like, so that the wireless audio receiving and playing functions are realized. The memory of the earphone can store a body temperature detection program, and the microprocessor can be used for calling the body temperature detection program stored in the memory and executing the following operations:

acquiring temperature data acquired by each temperature sensor;

Further, the temperature sensors include a first temperature sensor and a second temperature sensor respectively disposed on a first earphone and a second earphone of the earphone device, and the operation of determining the body temperature state according to the temperature data and a preset body temperature threshold interval includes:

Further, the temperature sensor includes a third temperature sensor and a fourth temperature sensor which are arranged in different position areas of any one of the earphones in the earphone device, and the operation of determining the body temperature state according to the temperature data and a preset body temperature threshold interval further includes:

Further, the operation of determining the body temperature state according to the temperature data and a preset body temperature threshold interval includes:

comparing the temperature data to the body temperature threshold interval;

Further, the operation of evaluating the suspected low-temperature abnormal state and/or the suspected high-temperature abnormal state according to the new low-temperature number and/or the new high-temperature number, and determining an effective abnormal state as the body-temperature state includes:

if the new low temperature times is larger than a preset first threshold, determining that the suspected low temperature abnormal state is an effective abnormal state, and determining that the body temperature state is a low temperature abnormal state;

and if the new low-temperature times and/or the new high-temperature times are smaller than or equal to the first threshold, returning to execute the operation of acquiring the temperature data acquired by each temperature sensor.

Further, after the measure for determining that the body temperature state is the normal state, the microprocessor may be further configured to call a body temperature detection program stored in the memory, and perform the following operations:

and clearing the low-temperature times and the high-temperature times, acquiring temperature data transmitted by the temperature sensor at intervals of a preset first time length, and returning to execute the operation of determining the body temperature state according to the temperature data and a preset body temperature threshold interval.

Further, the abnormal state includes a low-temperature abnormal state and a high-temperature abnormal state, and if the body temperature state is the abnormal state, the operation of outputting the body temperature abnormal prompt message includes:

Further, the operation of acquiring the temperature data collected by each temperature sensor comprises:

the body temperature detection method further comprises the following steps:

The embodiments of the earphone device and the computer-readable storage medium of the present invention can refer to the embodiments of the body temperature detection method of the present invention, and are not described herein again.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrases "comprising a component of' 8230; \8230;" does not exclude the presence of another like element in a process, method, article, or apparatus that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solutions of the present invention may be embodied in the form of a software product, which is stored in a storage medium (such as ROM/RAM, magnetic disk, optical disk) and includes instructions for enabling a terminal device (such as a mobile phone, a computer, a server, an air conditioner, or a network device) to execute the method according to the embodiments of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A body temperature detection method is characterized in that the body temperature detection method is applied to earphone equipment, temperature sensors are arranged at different positions of the earphone equipment, and the body temperature detection method comprises the following steps:

acquiring temperature data acquired by each temperature sensor;

2. The method as claimed in claim 1, wherein the temperature sensors comprise a first temperature sensor and a second temperature sensor respectively disposed on a first earphone and a second earphone of the earphone device, and the step of determining the body temperature state according to the temperature data and a preset body temperature threshold interval comprises:

3. The method as claimed in claim 1, wherein the temperature sensors include a third temperature sensor and a fourth temperature sensor disposed in different location areas of any one of the earphones, and the step of determining the body temperature status according to the temperature data and a preset body temperature threshold interval further includes:

4. The method as claimed in claim 1, wherein the step of determining the body temperature state according to the temperature data and a preset body temperature threshold interval comprises:

comparing the temperature data to the body temperature threshold interval;

5. The method according to claim 4, wherein the step of evaluating the suspected low-temperature abnormal state and/or the suspected high-temperature abnormal state according to the new low-temperature number and/or the new high-temperature number comprises:

6. The body temperature detecting method according to claim 4, further comprising, after the step of determining that the body temperature state is a normal state:

7. The method for detecting body temperature according to claim 1, wherein the abnormal state includes a low-temperature abnormal state and a high-temperature abnormal state, and the step of outputting the body temperature abnormal prompt message if the body temperature state is the abnormal state includes:

8. The method for detecting body temperature according to any one of claims 1 to 7, wherein the step of acquiring the temperature data collected by each of the temperature sensors comprises:

the body temperature detection method further comprises the following steps:

9. An earphone device, characterized in that the earphone device comprises: a memory, a processor and a body temperature detection program stored on the memory and executable on the processor, the body temperature detection program when executed by the processor implementing the steps of the body temperature detection method according to any one of claims 1 to 8.

10. A computer-readable storage medium, having a body temperature detection program stored thereon, which when executed by a processor implements the steps of the body temperature detection method according to any one of claims 1 to 8.