CN111855019B

Movatterモバイル変換

Info

Publication number: CN111855019B
Application number: CN202010731357.2A
Authority: CN
Inventors: 骆俊谕; 叶鑫; 王芬清; 李欢
Original assignee: Goertek Techology Co Ltd
Current assignee: Goertek Techology Co Ltd
Priority date: 2020-07-27
Filing date: 2020-07-27
Publication date: 2023-01-24
Anticipated expiration: 2040-07-27
Also published as: CN111855019A

Abstract

The application discloses temperature measurement method is applied to wrist equipment, includes: if the wrist-lifting action of the wrist-worn device wearer is detected, acquiring the alternative environment temperature acquired by the first temperature sensor according to a preset period; determining a target time period according to the change trend of the alternative environment temperature; the change trend of the alternative environment temperature corresponding to the target time period is not an increasing trend or a decreasing trend, and the time span of the target time period is greater than or equal to the preset time length; and determining the actual environment temperature according to the alternative environment temperature corresponding to the target time period. The accuracy of measuring the ambient temperature can be improved. The application also discloses a temperature measuring device, a wrist-worn device and a storage medium, which have the beneficial effects.

Description

Temperature measuring method and device, wrist-worn equipment and storage medium

Technical Field

The application relates to the technical field of intelligent wearable equipment, in particular to a temperature measuring method and device, wrist wearable equipment and a storage medium.

Background

The intelligent wearing equipment is a general name applying wearing technology to intelligently design daily wearing and develop wearable equipment, and the intelligent wearing equipment can comprise an intelligent watch, an intelligent bracelet, intelligent glasses and the like. The user can better perceive the information of the outside and the user through the intelligent wearable device, so that the information can be efficiently processed under the assistance of a computer and a network.

Carry out ambient temperature based on intelligent wearing equipment and detect the temperature situation that can be convenient for the user to know self institute place environment. However, for a wrist-worn device, when the user lifts the wrist, the wrist-worn device will be exposed to the external environment from the sleeve, and the external environment and the temperature inside the sleeve are different, so that the environmental temperature measured by the wrist-worn device is inaccurate.

Therefore, how to improve the accuracy of measuring the ambient temperature is a technical problem that needs to be solved by those skilled in the art.

Disclosure of Invention

The application aims to provide a temperature measuring method, a temperature measuring device, wrist-worn equipment and a storage medium, which can improve the accuracy of measuring the ambient temperature.

In order to solve the above technical problem, the present application provides a temperature measurement method applied to a wrist-worn device, the temperature measurement method including:

if the wrist-lifting action of the wrist-worn device wearer is detected, acquiring the alternative environment temperature acquired by the first temperature sensor according to a preset period;

determining a target time period according to the change trend of the alternative environment temperature; the change trend of the alternative environment temperature corresponding to the target time period is not an increasing trend or a decreasing trend, and the time span of the target time period is greater than or equal to the preset time length;

and determining the actual environment temperature according to the alternative environment temperature corresponding to the target time period.

Optionally, the method further includes:

and acquiring the body surface temperature of the user acquired by the second temperature sensor, and correcting the body surface temperature of the user according to the actual environment temperature to obtain the actual body temperature of the user.

Optionally, determining the target time period according to the variation trend of the candidate environment temperature includes:

determining the number of acquired alternative ambient temperatures;

if the number of the acquired alternative environment temperatures is larger than the preset number, adding the acquired alternative environment temperatures to a temperature value set, and clearing the number of the acquired alternative environment temperatures;

judging whether the trend of the alternative environment temperature in the temperature value set changing along with the time is an increasing trend or a decreasing trend;

if yes, clearing the alternative environment temperatures in the temperature value set, and determining the number of the obtained alternative environment temperatures;

if not, taking the time period corresponding to the alternative environment temperature in the temperature value set as the target time period.

Optionally, after determining that the trend of the alternative ambient temperature in the set of temperature values over time is an increasing trend or a decreasing trend, the method further includes:

and generating prompt information that the current environment temperature measurement has errors.

determining a period statistical parameter; wherein the initial value of the periodic statistical parameter is 2;

judging whether the trend of the change of the alternative environment temperature along with the time collected in the (i-2) th period, the (i-1) th period and the (i) th period is an increasing trend or a decreasing trend; the first temperature sensor is used for acquiring the alternative ambient temperature of the first temperature sensor at the wrist lifting moment, wherein i is the cycle number, i is larger than 2, the ith cycle is the current cycle, and the alternative ambient temperature acquired in the 1 st cycle is the alternative ambient temperature acquired by the first temperature sensor at the wrist lifting moment;

if so, executing preset operation on the value of the period statistical parameter; wherein, the preset operation comprises: judging whether the current value of the periodic statistical parameter is greater than 2, if so, subtracting 1 from the value of the periodic statistical parameter, and if not, keeping the current value of the periodic statistical parameter unchanged;

if not, adding 1 to the value of the periodic statistical parameter;

judging whether the value of the period statistical parameter is greater than or equal to a reference value N;

and if the value of the period statistical parameter is greater than or equal to the reference value N, taking the current period and a time period corresponding to N-1 periods before the current period as a target time period.

Optionally, determining the actual ambient temperature according to the alternative ambient temperature corresponding to the target time period includes:

removing the invalid alternative environment temperature from the alternative environment temperatures corresponding to the target time period to obtain an effective alternative environment temperature;

and taking the average value of the effective alternative environment temperatures as the actual environment temperature.

Optionally, the invalid alternative ambient temperature is an alternative ambient temperature corresponding to a target time period in which an absolute value of a difference between the invalid alternative ambient temperature and the median of the temperature is greater than a preset temperature difference, and the median of the temperature is a median of all alternative ambient temperatures in the target time period.

The application also provides a temperature measurement device, is applied to wrist and wears equipment, and the device includes:

the standby environment temperature acquisition module is used for acquiring the standby environment temperature acquired by the first temperature sensor according to a preset period if the wrist-lifting action of the wrist-worn device wearer is detected;

the target time period determining module is used for determining a target time period according to the change trend of the alternative environment temperature; the change trend of the alternative environment temperature corresponding to the target time period is not an increasing trend or a decreasing trend, and the time span of the target time period is greater than or equal to the preset time length;

and the actual environment temperature determining module is used for determining the actual environment temperature according to the alternative environment temperature corresponding to the target time period.

The application also provides a storage medium, on which a computer program is stored, which when executed implements the steps performed by the above temperature measurement method.

The application also provides wrist-worn equipment which comprises a motion detection device, a first temperature sensor, a second temperature sensor, a memory and a processor; the motion sensor is used for acquiring wrist-lifting motion signals; the first temperature sensor is used for collecting the outside temperature of the shell of the wrist-worn device and taking the outside temperature of the shell as the alternative environment temperature; the second temperature sensor is used for acquiring the body surface temperature of the user; a memory for storing a computer program; and the processor is used for realizing the steps of the temperature measuring method when calling the computer program in the memory.

The application provides a temperature measurement method, is applied to wrist and wears equipment, includes: if the wrist-lifting action of the wrist-worn device wearer is detected, acquiring the alternative environment temperature acquired by the first temperature sensor according to a preset period; determining a target time period according to the change trend of the alternative environment temperature; the change trend of the alternative environment temperature corresponding to the target time period is not an increasing trend or a decreasing trend, and the time span of the target time period is greater than or equal to the preset time length; and determining the actual environment temperature according to the alternative environment temperature corresponding to the target time period.

This application detects wrist-worn equipment wearer's the back of lifting the wrist action, acquires the alternative ambient temperature that first temperature sensor gathered many times according to predetermineeing the cycle, if the temperature in the wearer's sleeve is different with external environment, the alternative ambient temperature's that first temperature sensor gathered after the wearer lifts the wrist trend be the increment rate or decrement. According to the method and the device, the target time period with the time span larger than or equal to the preset time length and the change trend not increasing or decreasing is selected according to the change trend of the alternative temperature, namely the alternative environment temperature collected by the first temperature sensor in the target time period changes stably and approaches to the real environment temperature, and the actual environment temperature can be determined according to the alternative environment temperature corresponding to the target time period. This application can eliminate wrist and wear equipment from exposing the error of measuring ambient temperature when external environment in the sleeve, improves the accuracy of measuring ambient temperature. This application still provides a temperature measuring device, a wrist equipment of wearing and a storage medium simultaneously, has above-mentioned beneficial effect, no longer gives unnecessary details here.

Drawings

In order to more clearly illustrate the embodiments of the present application, the drawings needed for the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings can be obtained by those skilled in the art without inventive effort.

Fig. 1 is a flowchart of a temperature measuring method according to an embodiment of the present disclosure;

FIG. 2 is a flow chart of a method for analyzing alternative ambient temperature trends provided by an embodiment of the present application;

FIG. 3 is a flow chart of another method for analyzing alternative ambient temperature trends provided by embodiments of the present application;

fig. 4 is a schematic structural diagram of a wrist-worn device according to an embodiment of the present disclosure;

fig. 5 is a schematic structural diagram of a temperature measuring device according to an embodiment of the present disclosure.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all 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 application.

Referring to fig. 1, fig. 1 is a flowchart of a temperature measurement method according to an embodiment of the present disclosure.

The specific steps may include:

s101: if the wrist-lifting action of the wrist-worn device wearer is detected, acquiring the alternative environment temperature acquired by the first temperature sensor according to a preset period;

wherein, this embodiment can be applied to wrist and wear equipment, and wrist wears equipment and can include intelligent bracelet, intelligent wrist-watch etc.. The wrist-worn equipment can comprise a motion detection device, and whether a wrist-lifting action exists for a wearer of the wrist-worn equipment is judged according to a motion signal collected by the motion detection device. Specifically, the motion detection device can include acceleration sensor and gyroscope, and this embodiment can judge whether the wearer lifts the wrist according to the acceleration signal that acceleration sensor gathered and the angular velocity signal that the gyroscope gathered.

After detecting the wrist lifting action of the wrist wearing device wearer, the alternative environment temperature collected by the first temperature sensor can be acquired according to a preset period. First temperature sensor in this embodiment can be contact temperature sensor for gather wrist-worn equipment's equipment casing temperature, equipment casing can be the great material of coefficient of heat conductivity (like metal copper, stainless steel etc.) manufacturing, consequently when wrist-worn equipment is in the stable environment of a certain temperature for a long time, wrist-worn equipment's equipment casing temperature is the same with the temperature of environment of being located. The present embodiment may use the device case temperature collected by the first temperature sensor as the alternative ambient temperature.

S102: determining a target time period according to the change trend of the alternative environment temperature;

the wrist-mounted device is usually worn on the wrist part, so that the wrist-mounted device is located inside the sleeves when the wearer does not lift the wrist, and the wrist-mounted device is exposed to the external environment from inside the sleeves when the wearer lifts the wrist, so that the alternative environment temperature detected by the first temperature sensor when the wearer lifts the sleeves will change. For example, in an environment of 40 degrees celsius, the alternative ambient temperature will exhibit an increasing trend of change after the wearer lifts his wrist; in an environment of-20 degrees celsius, the alternative ambient temperature will exhibit a decreasing trend of change after the wearer lifts his wrist. After the wrist is lifted, the alternative environment temperature approaches the temperature of the environment where the wrist-worn device is located no matter the alternative environment temperature is increased or decreased, and finally the trend of change is stable.

The target time period is determined according to the change trend of the alternative environment temperature, the change trend of the alternative environment temperature corresponding to the target time period is not an increasing trend or a decreasing trend, and the time span of the target time period is larger than or equal to the preset time length. The target time period is a time period when the alternative environment temperature is equal to the temperature of the environment where the wrist-worn device is located. The definition of the incremental trend in this embodiment may be: the alternative environment temperature detected after each time in the target time period is higher than the alternative environment temperature detected before; the definition of the decreasing trend in this embodiment may be: each later detected alternate ambient temperature within the target time period is lower than the previously detected alternate ambient temperature. The value of the corresponding candidate ambient temperature for the target time period may be a plurality of discrete temperature values. The definition of the incremental trend in this embodiment may also be: and the variation trend of the fitting curve of all the alternative environment temperatures in the target time period along with the time variation is within a preset interval.

S103: and determining the actual environment temperature according to the alternative environment temperature corresponding to the target time period.

After the target time period in which the candidate environment temperature is stable is determined, the present embodiment may determine the actual environment temperature according to the candidate environment temperature corresponding to the target time period. In determining the actual ambient temperature, excessive or insufficient ambient temperature may be removed in order to reduce measurement errors.

On the basis that obtains actual ambient temperature, user's body surface temperature that the second temperature sensor that this embodiment can utilize wrist-worn equipment gathered to revise user's body surface temperature according to actual ambient temperature, obtain user's actual body temperature. The second temperature sensor can be thermopile temperature sensor (a non-contact temperature sensor), can utilize thermopile temperature sensor to measure user's body surface temperature, because user's body surface temperature often receives ambient temperature's influence, consequently this embodiment revises user body surface temperature according to actual ambient temperature and obtains user's actual body temperature (like oral cavity temperature, armpit temperature or rectum temperature etc.), and then carries out accurate evaluation to user's physiological conditions according to user's actual body temperature.

In the embodiment, after the wrist-lifting action of the wrist-worn device wearer is detected, the alternative environment temperature collected by the first temperature sensor is obtained for multiple times according to the preset period, and if the temperature in the sleeve of the wearer is different from the external environment, the change trend of the alternative environment temperature collected by the first temperature sensor after the wrist of the wearer is lifted is a gradual increase rate or a gradual decrease. In this embodiment, a target time period in which the time span is greater than or equal to the preset time length and the change trend is not increasing or decreasing is selected according to the change trend of the candidate temperature, that is, the candidate ambient temperature collected by the first temperature sensor in the target time period changes smoothly and approaches to the real ambient temperature, and further, the actual ambient temperature may be determined according to the candidate ambient temperature corresponding to the target time period. According to the wrist-worn equipment measuring method and device, the error of measuring the ambient temperature when the wrist-worn equipment is exposed to the external environment from the interior of the sleeve can be eliminated, and the accuracy of measuring the ambient temperature is improved.

Referring to fig. 2, fig. 2 is a flowchart of a method for analyzing a candidate ambient temperature trend provided in an embodiment of the present application, where the embodiment further describes S102 in the embodiment corresponding to fig. 1, and a further implementation may be obtained by combining the embodiment with the embodiment corresponding to fig. 1, where the embodiment may include the following steps:

s201: determining the number of acquired alternative ambient temperatures;

the obtained alternative environment temperature may be the alternative environment temperature obtained by the first temperature sensor according to a preset period after the wrist raising motion is detected, an initial value of the number of the obtained alternative environment temperatures is 0, and 1 is added to the number of the obtained alternative environment temperatures every preset period.

S202: if the number of the acquired alternative environment temperatures is larger than the preset number, adding the acquired alternative environment temperatures to a temperature value set, and clearing the number of the acquired alternative environment temperatures;

before this step, an operation of judging that the number of the acquired alternative ambient temperatures is greater than a preset number may exist, and if the number of the acquired alternative ambient temperatures is greater than the preset number, the acquired alternative ambient temperatures are added to the temperature value set so as to analyze a change trend of all the alternative ambient temperatures in the temperature value set along with time. The present embodiment may zero the number of acquired candidate ambient temperatures while adding the acquired candidate ambient temperatures to the temperature value set, so as to record the number of newly acquired candidate ambient temperatures.

S203: judging whether the trend of the alternative environment temperature in the temperature value set changing along with the time is an increasing trend or a decreasing trend; if so, clearing the alternative environment temperatures in the temperature value set, and entering a step of determining the number of the acquired alternative environment temperatures; if not, entering S204;

s204: and taking the time period corresponding to the alternative environment temperature in the temperature value set as a target time period.

As a further introduction to the corresponding embodiment of fig. 2, after determining that the trend of the alternative ambient temperature over time within the set of temperature values is an increasing trend or a decreasing trend, a prompt message indicating that the current ambient temperature measurement has an error may also be generated. Specifically, can vibrate or report the prompt tone through wrist-worn equipment in this embodiment and remind the user that there is the error in the current ambient temperature measurement.

Referring to fig. 3, fig. 3 is a flowchart of another method for analyzing alternative ambient temperature trends according to an embodiment of the present application, where this embodiment further describes S102 in the embodiment corresponding to fig. 1, and a further implementation may be obtained by combining this embodiment with the embodiment corresponding to fig. 1, where this embodiment may include the following steps:

s301: determining a period statistical parameter;

the period statistical parameter mentioned in this embodiment is information describing a period number of continuous discrete (non-increasing or decreasing) alternative environment temperatures acquired according to a preset period after the wrist raising motion is detected, and an initial value of the period statistical parameter is 2;

s302: judging whether the trend of the change of the alternative environment temperature along with the time collected in the (i-2) th period, the (i-1) th period and the (i) th period is an increasing trend or a decreasing trend; if yes, entering S303; if not, entering S304;

in the embodiment, at least three periods of acquired alternative environment temperatures are needed to determine whether the trend of the random time change of the alternative environment temperatures is an increasing trend or a decreasing trend, i is a period number, i is greater than 2, the ith period is the current period, and the alternative environment temperature acquired in the 1 st period is the alternative environment temperature acquired by the first temperature sensor at the wrist lifting moment.

S303: performing a preset operation on the value of the period statistical parameter;

based on determining whether the trend of the alternative environment temperature collected in the (i-2) th cycle, the (i-1) th cycle and the (i) th cycle along with the change of the time is an increasing trend or a decreasing trend, the current value of the cycle statistical parameter can be reduced by one (namely, the cycle number of the continuous discrete alternative environment temperature is reduced by one), and if the current value of the cycle statistical parameter is 2, the current value can be kept unchanged. Specifically, the preset operation performed on the value of the period statistic parameter in this embodiment may include: and judging whether the current value of the period statistical parameter is greater than 2, if so, subtracting 1 from the value of the period statistical parameter, and if so, keeping the current value of the period statistical parameter unchanged.

S304: adding 1 to the value of the period statistical parameter;

the step is established on the basis that the trend of the change of the alternative environment temperature along with the time collected in the (i-2) th cycle, the (i-1) th cycle and the (i) th cycle is determined not to be an increasing trend or a decreasing trend, and the current value of the cycle statistical parameter can be added with one, namely the cycle number of the continuous discrete alternative environment temperature is added with 1. The larger the value of the period statistical parameter is, the more the alternative environment temperature approaches the true environment temperature.

S305: judging whether the value of the period statistical parameter is greater than or equal to a reference value N; if yes, entering S306; if not, adding 1 to the value of i and entering S302;

s306: and taking the time period corresponding to the current period and N-1 periods before the current period as a target time period.

Before the step, an operation of judging whether the value of the period statistical parameter is greater than or equal to the reference value N may also exist, and if the value of the period statistical parameter is greater than or equal to the reference value N, the time periods corresponding to the current period and N-1 periods before the current period are taken as the target time periods.

The implementation process of the above embodiment is described below by using a specific example, if the alternative environment temperature of the 1 st cycle is 30 degrees celsius and the alternative environment temperature of the 2 nd cycle is 32 degrees celsius, at this time, if the alternative environment temperature of the 3 rd cycle is detected to be 31 degrees celsius, the value of the cycle statistical parameter is updated to be 3, and at this time, if the alternative environment temperature of the 3 rd cycle is detected to be 33 degrees celsius, the value of the cycle statistical parameter is 2. If the alternative environment temperature of the 5 th cycle is 30 degrees celsius, the alternative environment temperature of the 6 th cycle is 32 degrees celsius, and the value of the cycle statistical parameter in the 6 th cycle is 4, at this time, if the alternative environment temperature of the 7 th cycle is 31 degrees celsius, the value of the cycle statistical parameter is updated to 3, the value of the reference value N is 5, at this time, if the alternative environment temperature of the 7 th cycle is 33 degrees celsius, the value of the cycle statistical parameter is updated to 3, at this time, if the alternative environment temperature of the 7 th cycle is 31 degrees celsius, the value of the cycle statistical parameter is updated to 5, and the time period corresponding to the 3 rd cycle to the 7 th cycle is taken as the target time period.

Referring to fig. 4, fig. 4 is a schematic structural diagram of a wrist-worn device according to an embodiment of the present disclosure, where the wrist-worn device may include, but is not limited to, a microprocessor, a graphics processor, an audio module, a display module, a mobile communication module, a WiFi module, a motion detection device, a temperature detection module, a battery and a power management module. The microprocessor is used for finishing operations of instruction fetching, instruction execution, information exchange with an external memory and a logic component and the like, and is an operation control part of the intelligent wearable device. The graphics processor can draw the graphics content and drive the display module to perform graphics display. The memory may store various application programs and associated data. The display module may display information of the system processing module, such as pictures, videos, user interfaces, and the like. The audio module may include an audio decoding unit and a speaker unit, and may decode audio contents from the system processing module and generate sounds. The battery and power management module provides power and power management for the various modules of the device. The mobile communication module may be, but is not limited to, a 4G mobile communication module, a 5G mobile communication module, etc., by which the terminal device can achieve connection with an external network (e.g., the internet). The WiFi module may connect to a WiFi hotspot or local area network route, which in turn connects to an external network (e.g., the internet). The motion detection device includes but is not limited to an acceleration sensor, a gyroscope and the like, and can detect the motion state of the wearable device, such as whether a wrist-lifting action exists, the wearable device is lifted or put down, the stationary state and the like, and send the motion state of the wearable device to the microprocessor. The temperature detection module comprises a thermopile temperature sensor optical cover, a temperature detection module structural shell, a thermopile temperature sensor (i.e. the second temperature sensor mentioned in the corresponding embodiment of fig. 1), and a contact temperature sensor (i.e. the first temperature sensor mentioned in the corresponding embodiment of fig. 1). Including but not limited to NTC temperature sensors, thermocouple temperature sensors, or PN junction temperature sensors. The NTC Temperature sensor includes an NTC thermistor, and NTC (Negative Temperature Coefficient) refers to a thermistor phenomenon and material having a Negative Temperature Coefficient, in which resistance decreases exponentially with Temperature rise. A contact temperature sensor is already arranged in part of the thermoelectric temperature sensor and used for detecting the temperature of the chip, and in this case, an additional contact temperature sensor is not needed. Among them, the thermopile temperature sensor is used to measure an external surface temperature (e.g., forehead temperature), and the contact temperature sensor is used to measure an ambient temperature.

The process of body temperature detection using the wrist-worn device mentioned in the embodiment corresponding to fig. 4 is as follows:

after the body temperature detection function of the wrist strap device is opened by a user, the motion detection device of the wrist wearing device monitors the motion state of the wearing device in real time and sends the state information to the microprocessor.

If the motion detection device detects the wrist lifting action of the user, the micro-processing records the temperature mean value T0 of the contact temperature sensor obtained last time before the wrist lifting, and starts to obtain the temperature reading of the contact temperature sensor once every delta T time. Wherein the temperature mean T0 at the time of wrist lifting may be a temperature reading of the first contact temperature sensor. Detecting a lift in a motion state detection moduleThe wrist action state is started, the wearable device is in the ascending motion state until the wearable device is static (at the moment, a user aligns a receiving window of a thermopile sensor of the wearable device to the forehead), and n temperature readings are obtained within the period T1, wherein T is the period_a1 ,T_a2 ,T_a3 ,T_a4 ,…,T_an . If the above-mentioned T_a1 ,T_a2 ,T_a3 ,T_a4 ,…,T_an The readings show an increasing or decreasing trend, the microprocessor reminds the user that the accurate ambient temperature is not obtained at the moment in a certain mode (such as vibration, image display or sound playing) and needs the user to keep the wearable device exposed in the air environment, and the microprocessor continues to obtain the temperature readings of the contact temperature sensor at intervals of delta T until n temperature readings, T 'are obtained again in time T2'_a1 ,T’_a2 ,T’_a3 ,T’_a4 ,…,T’_an . If the above-mentioned T_a1 ,T_a2 ,T_a3 ,T_a4 ,…,T_an The readings do not show an increasing or decreasing trend, and there are only a few k discrete differences from the median with absolute values greater than Δ T_m0.5 The data of (2) can be discarded as invalid data. Averaging the remaining readings, i.e. ambient temperature mean T_a ＝(T_a1 +T_a2 +T_a3 +T_a4 +…+T_an ) And (n-k) as ambient temperature for subsequent data processing. If there are only a few k discrete differences from the median in the readings above, the absolute value is greater than Δ T_m0.5 The data of (2) can be discarded as invalid data. Averaging the remaining readings to obtain an ambient temperature average (i.e., the actual ambient temperature mentioned above), the ambient temperature average T_a ＝(T’_a1 +T’_a2 +T’_a3 +T’_a4 +…+T’_an ) And (n-k) as ambient temperature for subsequent data processing.

After the motion state detection module detects that the wearable device is static and obtains the ambient temperature mean value, the microprocessor continuously reads the readings T of the thermopile temperature sensor for m times_f1 ,T_f2 ,T_f3 ,T_f4 ,…,T_fm . The microprocessor utilizes the environment temperature mean value T obtained by the steps_a And readings T of m thermopile temperature sensors_f1 ,T_f2 ,T_f3 ,T_f4 ,…,T_fm Calculating to obtain the body temperature T of the human body through a certain environment temperature compensation algorithm_b1 ,T_b2 ,T_b3 ,T_b4 ,…,T_bm 。

If the calculated m human body temperatures are all in the range of the low value and the high value of the normal temperature of the human body, namely T_L ≤T_bi ≤T_H And 0 is<i ≦ m (e.g., T)_L Can be preset to a low value of the normal temperature of the human body, for example 35 ℃; t is a unit of_H Can be preset to a high value of the normal temperature of the human body, for example 37.3 ℃), the readings of the m thermopile temperature sensors are averaged T_b I.e. T_b ＝(T_b1 +T_b2 +T_b3 +T_b4 +…+T_bm ) And the microprocessor reminds the user of finishing the measurement in a certain mode (such as vibration or broadcast sound), and outputs the average value serving as the finally measured human body temperature to the user in a display or voice broadcast mode. If there is a small amount of T_bi <T_L And 0 is<And if i is less than or equal to m, discarding the data and then averaging the rest data, reminding the user of completing measurement by the microprocessor in a certain mode (such as vibration or broadcast sound), and outputting the average value serving as the finally measured human body temperature to the user in a display or voice broadcast mode. If T is present_H ≤T_bi The microprocessor reminds the user that the current measured temperature is higher through a certain mode (such as vibration or broadcast sound) and secondary temperature measurement needs to be carried out on the forehead again.

Referring to fig. 5, fig. 5 is a schematic structural diagram of a temperature measuring device according to an embodiment of the present disclosure;

the apparatus may include:

the standby environmenttemperature acquisition module 100 is configured to acquire a standby environment temperature acquired by the first temperature sensor according to a preset period if a wrist raising action of the wrist-worn device wearer is detected;

the target timeperiod determining module 200 is used for determining a target time period according to the change trend of the alternative environment temperature; the change trend of the alternative environment temperature corresponding to the target time period is not an increasing trend or a decreasing trend, and the time span of the target time period is greater than or equal to the preset time length;

and an actual ambienttemperature determining module 300, configured to determine an actual ambient temperature according to the candidate ambient temperature corresponding to the target time period.

According to the embodiment, after the wrist-lifting action of the wrist-wearing device wearer is detected, the alternative environment temperature collected by the first temperature sensor is obtained for multiple times according to the preset period, and if the temperature in the sleeves of the wearer is different from the external environment, the change trend of the alternative environment temperature collected by the first temperature sensor after the wrist-lifting of the wearer is the incremental rate or the incremental rate. According to the embodiment, the target time period is selected according to the change trend of the alternative temperature, wherein the time span is greater than or equal to the preset time length, and the change trend is not increased or decreased, that is, the alternative environment temperature collected by the first temperature sensor in the target time period changes stably and approaches to the real environment temperature, so that the actual environment temperature can be determined according to the alternative environment temperature corresponding to the target time period. According to the wrist-worn equipment measuring method and device, the error of measuring the ambient temperature when the wrist-worn equipment is exposed to the external environment from the interior of the sleeve can be eliminated, and the accuracy of measuring the ambient temperature is improved.

Further, the method also comprises the following steps:

and the body temperature detection module is used for acquiring the body surface temperature of the user acquired by the second temperature sensor, and correcting the body surface temperature of the user according to the actual environment temperature to obtain the actual body temperature of the user.

Further, the target timeperiod determining module 200 is configured to determine the number of the acquired alternative ambient temperatures; the system is also used for adding the acquired alternative environment temperatures to a temperature value set and clearing the number of the acquired alternative environment temperatures if the number of the acquired alternative environment temperatures is larger than a preset number; the device is also used for judging whether the trend of the alternative environment temperature changing along with the time in the temperature value set is an increasing trend or a decreasing trend; if so, clearing the alternative environment temperatures in the temperature value set, and entering a step of determining the number of the acquired alternative environment temperatures; if not, taking the time period corresponding to the alternative environment temperature in the temperature value set as a target time period.

Further, the method also comprises the following steps:

and the prompting module is used for generating prompting information of errors existing in the current environment temperature measurement after judging that the trend of the alternative environment temperature in the temperature value set along with the change of time is an increasing trend or a decreasing trend.

Further, the target time period determining module 200 is configured to determine a period statistical parameter; wherein the initial value of the period statistical parameter is 2; the system is also used for judging whether the trend of the alternative environment temperature collected in the (i-2) th period, the (i-1) th period and the (i) th period along with the change of time is an increasing trend or a decreasing trend; the first temperature sensor is used for acquiring the alternative ambient temperature of the first temperature sensor at the wrist lifting moment, wherein i is the cycle number, i is larger than 2, the ith cycle is the current cycle, and the alternative ambient temperature acquired in the 1 st cycle is the alternative ambient temperature acquired by the first temperature sensor at the wrist lifting moment; if so, executing preset operation on the value of the period statistical parameter; wherein, the preset operation comprises: judging whether the current value of the period statistical parameter is greater than 2, if so, subtracting 1 from the value of the period statistical parameter, and if so, keeping the current value of the period statistical parameter unchanged; if not, adding 1 to the value of the periodic statistical parameter; the device is also used for judging whether the value of the period statistical parameter is larger than or equal to a reference value N; and if the value of the period statistical parameter is greater than or equal to the reference value N, taking the time period corresponding to the current period and N-1 periods before the current period as a target time period.

Further, the actual ambienttemperature determination module 300 includes:

the data filtering unit is used for removing invalid alternative environment temperatures in the alternative environment temperatures corresponding to the target time period to obtain valid alternative environment temperatures;

and the mean value calculating unit is used for taking the mean value of the effective alternative environment temperatures as the actual environment temperature.

Further, the invalid alternative environment temperature is an alternative environment temperature corresponding to a target time period in which the absolute value of the difference between the invalid alternative environment temperature and the temperature median is greater than the preset temperature difference, and the temperature median is the median of all the alternative environment temperatures in the target time period.

Since the embodiments of the apparatus portion and the method portion correspond to each other, please refer to the description of the embodiments of the method portion for the embodiments of the apparatus portion, which is not repeated here.

The present application also provides a storage medium having a computer program stored thereon, which when executed, may implement the steps provided by the above-described embodiments. The storage medium may include: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

The application also provides wrist-worn equipment which comprises a motion detection device, a first temperature sensor, a second temperature sensor, a memory and a processor; the motion sensor is used for acquiring a wrist lifting motion signal; the first temperature sensor is used for collecting the outside temperature of the shell of the wrist-worn device and taking the outside temperature of the shell as the alternative environment temperature; the second temperature sensor is used for acquiring the body surface temperature of the user; the memory for storing a computer program; the processor is configured to implement the solution for temperature measurement in the present application when the computer program in the memory is called.

The embodiments are described in a progressive manner in the specification, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. The device disclosed by the embodiment corresponds to the method disclosed by the embodiment, so that the description is simple, and the relevant points can be referred to the method part for description. It should be noted that, for those skilled in the art, without departing from the principle of the present application, the present application can also make several improvements and modifications, and those improvements and modifications also fall into the protection scope of the claims of the present application.

It is further noted that, in the present specification, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, 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," "8230," "8230," or "comprising" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

Claims

1. A temperature measurement method is applied to wrist-worn equipment and comprises the following steps:

if the wrist-lifting action of the wrist-worn device wearer is detected, acquiring the alternative environment temperature acquired by the first temperature sensor according to a preset period; the alternative environment temperature is the equipment shell temperature acquired by the first temperature sensor;

determining a target time period according to the change trend of the alternative environment temperature; the change trend of the alternative environment temperature corresponding to the target time period is not an increasing trend or a decreasing trend, and the time span of the target time period is greater than or equal to a preset time length;

and determining the actual ambient temperature according to the alternative ambient temperature corresponding to the target time period so as to eliminate the error of measuring the ambient temperature when the wrist-worn device is exposed to the external environment from the inside of the sleeve.

2. The temperature measurement method according to claim 1, further comprising:

3. The temperature measuring method according to claim 1, wherein determining the target time period according to the trend of the candidate environmental temperature includes:

determining the number of acquired alternative ambient temperatures;

if the number of the acquired alternative environment temperatures is larger than a preset number, adding the acquired alternative environment temperatures to a temperature value set;

4. The method according to claim 3, further comprising, after determining that the trend of the alternative ambient temperature over time within the set of temperature values is an increasing trend or a decreasing trend:

5. The temperature measurement method according to claim 1, wherein determining a target time period according to the trend of change of the candidate environmental temperature comprises:

determining a period statistical parameter; wherein the initial value of the period statistical parameter is 2;

judging whether the trend of the alternative environment temperature collected in the (i-2) th period, the (i-1) th period and the (i) th period along with the change of the time is an increasing trend or a decreasing trend; the temperature sensor is used for acquiring the temperature of the environment, wherein i is a cycle number, i is larger than 2, the ith cycle is a current cycle, and the alternative environment temperature acquired in the 1 st cycle is the alternative environment temperature acquired by the first temperature sensor at the wrist lifting moment;

if so, executing preset operation on the value of the period statistical parameter; wherein the preset operation comprises: judging whether the current value of the periodic statistic parameter is greater than 2, if so, subtracting 1 from the value of the periodic statistic parameter, and if not, keeping the current value of the periodic statistic parameter unchanged;

if not, adding 1 to the value of the periodic statistical parameter;

and if the value of the period statistical parameter is greater than or equal to the reference value N, taking the current period and a time period corresponding to N-1 periods before the current period as the target time period.

6. The temperature measurement method according to claim 1, wherein determining the actual ambient temperature according to the candidate ambient temperature corresponding to the target time period comprises:

7. The temperature measurement method according to claim 6, wherein the invalid candidate ambient temperature is a candidate ambient temperature corresponding to the target time period in which an absolute value of a difference from a median temperature is greater than a preset temperature difference, and the median temperature is a median of all candidate ambient temperatures in the target time period.

8. A temperature measuring device, applied to a wrist-worn apparatus, comprising:

the standby environment temperature acquisition module is used for acquiring standby environment temperature acquired by the first temperature sensor according to a preset period if the wrist-lifting action of the wrist-worn device wearer is detected; the alternative environment temperature is the equipment shell temperature acquired by the first temperature sensor;

the target time period determining module is used for determining a target time period according to the change trend of the alternative environment temperature; the change trend of the alternative environment temperature corresponding to the target time period is not an increasing trend or a decreasing trend, and the time span of the target time period is greater than or equal to a preset time length;

and the actual environment temperature determining module is used for determining the actual environment temperature according to the alternative environment temperature corresponding to the target time period so as to eliminate the error of measuring the environment temperature when the wrist-worn device is exposed to the external environment from the inside of the sleeve.

9. A wrist-worn device comprising a motion detection means, a first temperature sensor, a second temperature sensor, a memory and a processor;

the motion detection device is used for collecting wrist-lifting motion signals;

the first temperature sensor is used for collecting the temperature of the equipment shell of the wrist-worn equipment and taking the temperature of the equipment shell as the alternative environment temperature;

the second temperature sensor is used for acquiring the body surface temperature of the user;

the memory is used for storing a computer program;

the processor, when invoking the computer program in the memory, implementing the steps of the temperature measurement method of any of claims 1 to 7.

10. A storage medium having stored thereon computer-executable instructions which, when loaded and executed by a processor, carry out the steps of a temperature measurement method as claimed in any one of claims 1 to 7.