CN114659674B - Temperature measurement function calibration method, system, device, charging base and medium - Google Patents

Abstract

The application discloses a temperature measurement function calibration method, a system, a device, a charging base and a medium, wherein the method comprises the following steps: when detecting that the wearable equipment needs to calibrate a temperature measurement function, receiving first temperature data which are sent by the wearable equipment and are measured in a first preset period, and acquiring second temperature data which are measured in the first preset period by a temperature acquisition module arranged on the charging base; determining a temperature compensation value based on the first temperature data and the second temperature data; and sending the temperature compensation value to the wearable device for the wearable device to calibrate a temperature measurement function of the wearable device based on the temperature compensation value. The temperature measuring device and the temperature measuring method improve accuracy of temperature measurement of the wearable device.

Description

Temperature measurement function calibration method, system, device, charging base and medium

Technical Field

The application relates to the field of wearable equipment, in particular to a temperature measurement function calibration method, a temperature measurement function calibration system, a temperature measurement function calibration device, a charging base and a temperature measurement medium.

Background

Wearable equipment (including intelligent bracelet, intelligent wrist-watch etc.) possesses the ability of measuring temperature, and its temperature measurement mode is contact. The wearable device can provide relatively accurate temperature variation through long-term monitoring of skin temperature because it has two characteristics of being worn for a long period and being in close contact with the human body.

However, as the usage time of the wearable device is prolonged, the wearable device may face the problems of poor battery performance, aging of elements, dirt of a detection window, and the like, so that the temperature measured by the wearable device is higher than the real temperature or lower than the real temperature, that is, a deviation exists between a temperature measurement result and the real temperature, and the temperature cannot be accurately measured.

Disclosure of Invention

The application mainly aims to provide a temperature measurement function calibration method, a temperature measurement function calibration system, a temperature measurement function calibration device, a charging base and a charging medium, and aims to solve the technical problem of how to improve the accuracy of temperature measurement of wearable equipment.

In order to achieve the above object, the present application provides a temperature measurement function calibration method applied to a charging base, the temperature measurement function calibration method comprising:

When detecting that the wearable equipment needs to calibrate a temperature measurement function, receiving first temperature data which are sent by the wearable equipment and are measured in a first preset period, and acquiring second temperature data which are measured in the first preset period by a temperature acquisition module arranged on the charging base;

determining a temperature compensation value based on the first temperature data and the second temperature data;

And sending the temperature compensation value to the wearable device for the wearable device to calibrate a temperature measurement function of the wearable device based on the temperature compensation value.

The method for measuring the temperature of the wearable device includes, when it is detected that the wearable device needs to calibrate the temperature measurement function, receiving first temperature data measured in a first preset period sent by the wearable device, and obtaining second temperature data measured in the first preset period by a temperature acquisition module set in the charging base, where the second temperature data is measured in the first preset period, the method includes:

When effective contact with the wearable equipment is detected, acquiring third temperature data measured by the temperature acquisition module in a second preset period, and receiving fourth temperature data transmitted by the wearable equipment and measured in the second preset period;

Determining a calibration judgment parameter based on the third temperature data and the fourth temperature data;

and if the calibration judgment parameter is greater than or equal to a preset calibration judgment parameter threshold, determining that the wearable equipment needs to calibrate a temperature measurement function.

Illustratively, the method further comprises:

based on the temperature compensation value and the calibration judgment parameter, adjusting the preset calibration judgment parameter threshold value to obtain an adjusted preset calibration judgment parameter threshold value;

and judging through the adjusted preset calibration judgment parameter threshold value when judging the magnitude between the calibration judgment parameter and the preset calibration judgment parameter threshold value next time.

Exemplary, when detecting that there is a wearable device that needs to calibrate a temperature measurement function, the method includes receiving first temperature data measured in a first preset period sent by the wearable device, and obtaining second temperature data measured in the first preset period by a temperature acquisition module set in the charging base, where the second temperature data includes:

When detecting that the wearable equipment needs to calibrate a temperature measurement function, charging the wearable equipment, and monitoring fifth temperature data acquired by a temperature acquisition module arranged on the charging base;

After the temperature of the charging base is determined to reach the preset temperature based on the fifth temperature data, first temperature data, which are sent by the wearable equipment and are measured in a first preset period, are received, and second temperature data, which are measured in the first preset period, of a temperature acquisition module arranged on the charging base are obtained.

The method for determining that the temperature of the charging base reaches the preset temperature based on the fifth temperature data includes, after the temperature of the charging base reaches the preset temperature, receiving first temperature data measured in a first preset period sent by the wearable device, and before obtaining second temperature data measured in the first preset period by a temperature acquisition module set in the charging base, including:

After the temperature of the charging base reaches a charging temperature peak value based on the fifth temperature data, controlling a heating module arranged on the charging base to heat the charging base;

When the temperature of the charging base reaches the preset temperature, the heating module is controlled to stop heating the charging base.

In addition, in order to achieve the above purpose, the application also provides a charging base, which comprises a heat conducting piece, a temperature acquisition module and a wireless communication module;

The heat conducting piece is fixedly connected with the temperature acquisition module and used for introducing heat of the wearable equipment when the heat conducting piece is in effective contact with the wearable equipment;

The temperature acquisition module is used for acquiring the temperature of the heat conducting piece so as to obtain the temperature of the charging base;

The wireless communication module is used for establishing communication connection with the wearable equipment so as to receive temperature data sent by the wearable equipment.

Illustratively, the charging base further includes a heating module;

the heating module is used for heating the charging base, so that the temperature of the charging base can reach the preset temperature.

In addition, in order to achieve the above object, the present application also provides a temperature measurement function calibration system, which includes a wearable device and a charging base;

the wearable device is used for: when the temperature measurement function needs to be calibrated, first temperature data measured in a first preset period of time are sent to the charging base; receiving a temperature compensation value sent by the charging base, and calibrating the temperature measurement function based on the temperature compensation value;

the charging base is used for: when detecting that the wearable equipment needs to calibrate a temperature measurement function, receiving first temperature data which are sent by the wearable equipment and are measured in a first preset period, and acquiring second temperature data which are measured in the first preset period by a temperature acquisition module arranged on the charging base; and determining a temperature compensation value based on the first temperature data and the second temperature data, and sending the temperature compensation value to the wearable device.

In addition, in order to achieve the above object, the present application also provides a temperature measurement function calibration device applied to a charging base, the temperature measurement function calibration device comprising:

The receiving module is used for receiving first temperature data which are sent by the wearable equipment and are measured in a first preset period when the wearable equipment is detected to have the function of calibrating temperature measurement, and obtaining second temperature data which are measured in the first preset period by the temperature acquisition module arranged on the charging base;

A first determination module for determining a temperature compensation value based on the first temperature data and the second temperature data;

and the sending module is used for sending the temperature compensation value to the wearable device so that the wearable device can calibrate the temperature measurement function of the wearable device based on the temperature compensation value.

In addition, in order to achieve the above object, the present application also provides a charging base including a memory, a processor, and a temperature measurement function calibration program stored on the memory and executable on the processor, which when executed by the processor, implements the steps of the temperature measurement function calibration method as described above.

In addition, in order to achieve the above object, the present application also provides a computer-readable storage medium having stored thereon a temperature measurement function calibration program which, when executed by a processor, implements the steps of the temperature measurement function calibration method as described above.

Compared with the prior art, the temperature measurement result of the wearable device has deviation from the real temperature, so that the temperature can not be accurately measured, the temperature compensation value is obtained by acquiring the difference between the temperature data measured by the wearable device and the temperature data measured by the charging base, and the temperature measurement function of the wearable device is calibrated by the temperature compensation value, so that the calibration of the wearable device by taking the temperature data acquired by the charging base as a reference is realized. It can be understood that the charging base has no battery, the problem of poor performance of the battery cannot be faced, the contact with human skin is not needed, and the window cannot be polluted, so that the deviation between the temperature data measured by the charging base and the real temperature is far smaller than the deviation between the temperature measurement result measured by the wearable device and the real temperature, the deviation between the temperature measurement result measured by the wearable device and the real temperature can be greatly reduced by adjusting the temperature data measured by the charging base, and the accuracy of the temperature measurement of the wearable device is improved.

Drawings

FIG. 1 is a flow chart of a first embodiment of a temperature measurement function calibration method of the present application;

FIG. 2 is a schematic diagram of a temperature profile according to a first embodiment of the temperature measurement function calibration method of the present application;

FIG. 3 is a flow chart of a second embodiment of the temperature measurement function calibration method of the present application;

FIG. 4 is a schematic view of a charging base according to an embodiment of the present application;

FIG. 5 is a schematic diagram of a hardware operating environment according to an embodiment of the present application.

Reference numerals illustrate:

Reference numerals	Name of the name	Reference numerals	Name of the name
				100	Charging base	110	Heat conducting piece
120	Temperature acquisition module	130	Wireless communication module
				140	Heating module

The achievement of the objects, functional features and advantages of the present application will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application.

The application provides a temperature measurement function calibration method, referring to fig. 1, fig. 1 is a flow chart of a first embodiment of the temperature measurement function calibration method of the application.

Embodiments of the present application provide embodiments of a temperature measurement function calibration method, it being noted that although a logic sequence is shown in the flow chart, in some cases the steps shown or described may be performed in a different order than that shown or described herein. The temperature measurement function calibration method can be applied to the charging base. The temperature measurement function calibration method comprises the following steps:

step S10, when detecting that the wearable device needs to calibrate a temperature measurement function, receiving first temperature data which are sent by the wearable device and are measured in a first preset period, and acquiring second temperature data which are measured in the first preset period by a temperature acquisition module arranged on the charging base.

When carrying out the calibration of temperature measurement function to wearable equipment through charging the base, need the effective contact between wearable equipment and the charging base, this effective contact is the contact between the heat conduction spare that has better heat conduction ability that sets up in charging base and the wearable equipment, this can make both after effective contact, the heat of wearable equipment can be transmitted to the charging base fast to reduce the time consuming of calibration in-process, realize quick calibration.

The heat conducting member may be made of high heat conductivity material (AlN, BN, etc.), or may be made of common material (common metal (iron, copper, etc.)) that is, high heat conductivity material in contact with each other, so that heat can be conducted well. Of course, since the material with high thermal conductivity has better heat conducting capability, the heat conducting member is preferably a material with high thermal conductivity.

For example, since the wearable device is mainly used for monitoring the body temperature of a human body, the temperature measurement function is mainly used for measuring the body temperature, and can be used for measuring non-body temperatures including air temperature and water temperature.

For example, the first preset period may be set as needed, only by satisfying that the temperature data existing in the first preset period is stationary around the preset temperature. In particular, the second temperature data is stationary at the preset temperature, and the first temperature data is stationary only around the preset temperature due to a deviation from the real temperature.

The accuracy of the temperature measurement function of the wearable device is also related to the ambient temperature (i.e. the temperature that the wearable device needs to measure), for example. For example, the environment temperature is 30 degrees, the temperature measured by the wearable device is 28 degrees, the environment temperature is 25 degrees, the temperature measured by the wearable device is 24 degrees, and the difference between the two temperatures can be found, i.e. the accuracy of the temperature measurement function of the wearable device under different environment temperatures is different. Therefore, the preset temperature is preferably the environmental temperature of the main working environment of the wearable device, for example, the human body temperature is about 37 degrees, and the preset temperature may be set to 37 degrees.

When the wearable device is detected to exist and the temperature measurement function needs to be calibrated, the temperature measurement function of the wearable device is calibrated through the first temperature data and the second temperature data.

The method for measuring the temperature of the wearable device includes, when it is detected that the wearable device needs to calibrate the temperature measurement function, receiving first temperature data measured in a first preset period sent by the wearable device, and obtaining second temperature data measured in the first preset period by a temperature acquisition module set in the charging base, where the second temperature data is measured in the first preset period, the method includes:

step a, when effective contact with the wearable equipment is detected, acquiring third temperature data measured by the temperature acquisition module in a second preset period, and receiving fourth temperature data transmitted by the wearable equipment and measured in the second preset period.

When an effective contact with the wearable device is detected, the acquired temperature data includes contact data before contact in addition to temperature data after contact, i.e. the start time of the second preset period is before the effective contact, and since both the temperature of the wearable device and the temperature of the charging base are changing without being stationary when in effective contact with the wearable device, the end time of the second preset period is after the effective contact. In addition, similar to the first preset period, the temperature data corresponding to the second preset period also needs to be stationary.

And b, determining a calibration judgment parameter based on the third temperature data and the fourth temperature data.

The calibration judgment parameters are as follows: the charging base and the wearable device are used for measuring the same temperature, and the difference value between the actual measured value of the charging base and the actual measured value of the wearable device is obtained.

Because the wearable device is kept in contact with the human body for a long time before the charging base is in effective contact with the wearable device, the temperature of the wearable device is basically consistent with the human body, and the charging base is in direct contact with air, and because the air temperature is generally smaller than the body temperature, when the charging base is in effective contact with the wearable device, the temperature is diffused from the wearable device to the charging base, namely, the heat of the wearable device is conducted to the heat conducting piece on the charging base through the heat conducting piece on the wearable device, and the conduction is stopped when the temperature of the wearable device and the temperature are consistent.

Referring to fig. 2, 201 is a temperature curve generated based on fourth temperature data, 202 is a temperature curve generated based on third temperature data, wherein the abscissa is time and the ordinate is temperature. It can be appreciated that before the time point a, the temperature of the charging base is stabilized at the air temperature, and the temperature of the wearable device is stabilized at the body temperature; after the time point A and before the time point B, the wearable equipment is separated from the human body, at the moment, the heat of the wearable equipment is spread into the air, so that the temperature is reduced, and the temperature of the charging base is kept unchanged in the process; at the time point B, the charging base is in effective contact with the wearable equipment, at the moment, heat of the wearable equipment is rapidly conducted to the charging base through the heat conducting piece on the charging base, so that the temperature of the wearable equipment is rapidly reduced, the temperature of the charging base is rapidly increased, and at the time point C, the temperature of the charging base and the temperature of the wearable equipment are consistent for the first time and are higher than the air temperature; after the time point C and before the time point D, as the temperature of the charging base and the temperature of the wearable equipment are higher than the air temperature, the charging base and the wearable equipment can radiate heat into the air, and the heat radiation speeds of the charging base and the wearable equipment are different, so that heat can be mutually conducted between the charging base and the air, and after the time point D, the temperature of the charging base and the wearable equipment tends to be stable; and because the wearable equipment is in a working state, heat can be generated when the wearable equipment works, so that the temperature after being stabilized is higher than the air temperature.

It can be understood that after D, since the temperatures between the charging base and the wearable device are the same, the temperature difference between 201 and 202 is the temperature difference between the charging base and the wearable device at the same time point, i.e. the D value in the figure is the calibration judgment parameter.

And c, if the calibration judgment parameter is greater than or equal to a preset calibration judgment parameter threshold, determining that the wearable equipment needs to calibrate a temperature measurement function.

The preset calibration judgment parameter threshold value can be set according to needs, and the embodiment is not particularly limited.

If the calibration judgment parameter is smaller than the preset calibration judgment parameter threshold, the temperature measurement function of the wearable device is accurate, calibration of the temperature measurement function is not needed, and the wearable device is charged.

And step S20, determining a temperature compensation value based on the first temperature data and the second temperature data.

For convenience in determining whether the temperature data are stable, a first curve can be drawn through the first temperature data, a second curve can be drawn through the second temperature data, and the first curve and the second curve are displayed in the same curve chart in a time synchronization mode, so that real-time temperatures of the wearable equipment and the charging base at a certain moment can be intuitively fed back.

The temperature compensation value is the difference between the temperature of the wearable device and the temperature of the charging base at a certain moment after the temperature data is stable near the preset temperature.

Step S30, sending the temperature compensation value to the wearable device, so that the wearable device calibrates a temperature measurement function of the wearable device based on the temperature compensation value.

The temperature of the charging base is used as a reference value, the difference value is the error when the temperature of the wearable equipment is measured, the temperature measured by the wearable equipment is corrected through the temperature compensation value, and the calibration work can be completed. For example, the temperature compensation value is positive, the correction process is to subtract the temperature compensation value from the actual measurement value of the wearable device; in another example, the temperature compensation value is negative, and the correction process is to add the temperature compensation value to the actual measurement value of the wearable device.

Exemplary, the charging base and the wearable device communicate with each other through a wireless communication module (both of receiving the first temperature data and transmitting the temperature compensation value are realized through communication), and the communication modes may include bluetooth, wiFi and the like.

Illustratively, the temperature measurement function calibration method further includes:

Step d, adjusting the preset calibration judgment parameter threshold value based on the temperature compensation value and the calibration judgment parameter to obtain an adjusted preset calibration judgment parameter threshold value;

and e, judging through the adjusted preset calibration judgment parameter threshold value when judging the size between the calibration judgment parameter and the preset calibration judgment parameter threshold value next time.

Since the temperature compensation values corresponding to different ambient temperatures are different, and the higher the ambient temperature is, the larger the temperature compensation value is, and the calibration judgment parameter is obtained at the ambient temperature with lower temperature. It can be appreciated that when the calibration judgment parameter changes are not obvious, the temperature compensation value may be larger at a higher ambient temperature, so in order to avoid that when the calibration judgment parameter is smaller than the preset calibration judgment parameter threshold value but the temperature compensation value is larger, the temperature measurement function of the wearable device is not calibrated, so that the accuracy of the measurement temperature of the wearable device is reduced, and the preset calibration judgment parameter threshold value can be adjusted by the temperature compensation value. It can be understood that when the preset calibration judgment parameter threshold is adjusted, the temperature compensation value and the preset calibration judgment parameter threshold are inversely related, that is, when the calibration judgment parameters are basically the same, the larger the temperature compensation value, the more the temperature measurement function of the wearable device needs to be calibrated, that is, when the calibration judgment parameters are smaller, the temperature measurement function of the wearable device needs to be calibrated. For example, assuming that the calibration determination parameter 1 is 1.9 degrees and the preset calibration determination parameter threshold is 2 degrees, it may be determined that calibration of the temperature measurement function of the wearable device is not required; the calibration judgment parameter 2 is 2 degrees, when the calibration judgment parameter 2 is 2 degrees, the temperature compensation value is 4 degrees, and the temperature compensation value is 3 degrees, namely the temperature measurement function of the wearable device needs to be calibrated, at the moment, the temperature compensation value is 4 degrees and is obviously more than 3 degrees, and in fact, when the calibration judgment parameter 1 is 1.9 degrees, the measured temperature compensation value is 3.5; therefore, if the preset calibration judgment parameter threshold is 2 degrees, a situation that the temperature measurement function of the wearable device needs to be calibrated but not calibrated occurs, and in order to avoid the situation, the preset calibration judgment parameter threshold needs to be adjusted, that is, the preset calibration judgment parameter threshold is adjusted to be smaller, so that when the calibration judgment parameter is smaller than 2 degrees (for example, 1.6 degrees), the temperature measurement function of the wearable device is also determined to be calibrated.

For example, the relationship between the adjustment amplitude of the preset calibration judgment parameter threshold and the temperature compensation value may be set according to needs, and the embodiment is not particularly limited.

It can be understood that the process of adjusting the preset calibration judgment parameter threshold is to correct the process of judging whether the wearable device needs to calibrate the temperature measurement function, so that the temperature measurement function of the wearable device is ensured to be calibrated when the temperature measurement function of the wearable device needs to be calibrated, and the accuracy of measuring the temperature of the wearable device is improved.

Compared with the prior art, the temperature measurement result of the wearable device has deviation from the real temperature, so that the temperature can not be accurately measured, the temperature compensation value is obtained by acquiring the difference between the temperature data measured by the wearable device and the temperature data measured by the charging base, and the temperature measurement function of the wearable device is calibrated by the temperature compensation value, so that the calibration of the wearable device by taking the temperature data acquired by the charging base as a reference is realized. It can be understood that the charging base has no battery, the problem of poor performance of the battery cannot be faced, the contact with human skin is not needed, and the window cannot be polluted, so that the deviation between the temperature data measured by the charging base and the real temperature is far smaller than the deviation between the temperature measurement result measured by the wearable device and the real temperature, the deviation between the temperature measurement result measured by the wearable device and the real temperature can be greatly reduced by adjusting the temperature data measured by the charging base, and the accuracy of the temperature measurement of the wearable device is improved.

Exemplary, referring to fig. 3, a second embodiment is provided based on a first embodiment of the temperature measurement function calibration method of the present application, where when it is detected that there is a wearable device that needs to calibrate a temperature measurement function, the method includes receiving first temperature data measured in a first preset period sent by the wearable device, and obtaining second temperature data measured in the first preset period by a temperature acquisition module disposed on the charging base, where the second temperature data includes:

step A10, when detecting that the wearable equipment needs to calibrate a temperature measurement function, charging the wearable equipment, and monitoring fifth temperature data acquired by a temperature acquisition module arranged on a charging base;

And step A20, after the temperature of the charging base is determined to reach the preset temperature based on the fifth temperature data, receiving first temperature data which are sent by the wearable equipment and are measured in a first preset period, and acquiring second temperature data which are measured in the first preset period by a temperature acquisition module arranged on the charging base.

In the process of charging the wearable device, the temperature of the charging base can be increased, so that the purpose of increasing the temperature of the charging base is to create an environment with the environment temperature being the body temperature for the wearable device, and therefore, the second temperature data can be measured and the first temperature data can be received at the preset temperature.

The method for determining that the temperature of the charging base reaches the preset temperature based on the fifth temperature data includes, after the temperature of the charging base reaches the preset temperature, receiving first temperature data measured in a first preset period sent by the wearable device, and before obtaining second temperature data measured in the first preset period by a temperature acquisition module set in the charging base, including:

F, after determining that the temperature of the charging base reaches a charging temperature peak value based on the fifth temperature data, controlling a heating module arranged on the charging base to heat the charging base;

And g, controlling the heating module to stop heating the charging base when the temperature of the charging base reaches a preset temperature.

When the charging base charges the wearable device, both can generate heat, but the generated heat is limited, and the temperature of the charging base can not reach the preset temperature, so that the charging base can not be heated up through charging after the temperature of the charging base reaches the charging temperature peak value. It can be understood that the temperature of the charging base can reach the preset temperature by directly charging the wearable device only when the charging temperature peak value is greater than or equal to the preset temperature; if the charging temperature peak value is smaller than the preset temperature, the temperature of the charging base cannot reach the preset temperature only by charging the wearable device.

When the temperature of the charging base cannot reach the preset temperature by charging the wearable device, the charging base is required to be heated through the heating module arranged on the charging base, and the charging of the wearable device can be continued or stopped at the moment.

According to the embodiment, the wearable device is charged, the charging base is heated through the heating module, and the temperature of the charging base is raised to the preset temperature, so that the first temperature data and the second temperature data are measured at the preset temperature, and the accuracy of the temperature compensation value is improved.

Referring to fig. 4, fig. 4 is a schematic structural diagram of a charging base 100 according to an embodiment of the present application, where the charging base 100 includes a heat conducting member 110, a temperature collecting module 120 and a wireless communication module 130;

the heat conducting member 110 is fixedly connected with the temperature acquisition module 120, and is used for introducing heat of the wearable device when the heat conducting member is in effective contact with the wearable device;

the temperature collection module 120 is configured to collect the temperature of the heat conducting member 110 to obtain the temperature of the charging base;

The wireless communication module 130 is configured to establish communication connection with the wearable device, so as to receive temperature data sent by the wearable device.

Illustratively, the charging base further includes a heating module 140;

the heating module 140 is configured to heat the charging base, so that the temperature of the charging base can reach a preset temperature.

The specific implementation manner of the charging base is basically the same as that of each embodiment of the temperature measurement function calibration method, and is not repeated here.

In addition, the application also provides a temperature measurement function calibration system, which comprises a wearable device and a charging base;

the wearable device is used for: when the temperature measurement function needs to be calibrated, first temperature data measured in a first preset period of time are sent to the charging base; receiving a temperature compensation value sent by the charging base, and calibrating the temperature measurement function based on the temperature compensation value;

the charging base is used for: when detecting that the wearable equipment needs to calibrate a temperature measurement function, receiving first temperature data which are sent by the wearable equipment and are measured in a first preset period, and acquiring second temperature data which are measured in the first preset period by a temperature acquisition module arranged on the charging base; and determining a temperature compensation value based on the first temperature data and the second temperature data, and sending the temperature compensation value to the wearable device.

For example, when it is detected that the wearable device needs to calibrate the temperature measurement function, the charging base is further configured to, after receiving first temperature data measured in a first preset period sent by the wearable device and acquiring second temperature data measured in the first preset period by the temperature acquisition module of the charging base,: when effective contact with the wearable equipment is detected, acquiring third temperature data measured by the temperature acquisition module in a second preset period, and receiving fourth temperature data transmitted by the wearable equipment and measured in the second preset period; determining a calibration judgment parameter based on the third temperature data and the fourth temperature data; and if the calibration judgment parameter is greater than or equal to a preset calibration judgment parameter threshold, determining that the wearable equipment needs to calibrate a temperature measurement function.

Illustratively, the charging base is further configured to: based on the temperature compensation value and the calibration judgment parameter, adjusting the preset calibration judgment parameter threshold value to obtain an adjusted preset calibration judgment parameter threshold value; and judging through the adjusted preset calibration judgment parameter threshold value when judging the magnitude between the calibration judgment parameter and the preset calibration judgment parameter threshold value next time.

The method includes the steps that when the fact that the wearable device needs to calibrate a temperature measurement function is detected, first temperature data, which are sent by the wearable device and are measured in a first preset period, are received, second temperature data, which are measured in the first preset period, of a temperature acquisition module of the charging base are obtained, and the charging base is further used for: when detecting that the wearable equipment needs to calibrate a temperature measurement function, charging the wearable equipment, and monitoring fifth temperature data acquired by a temperature acquisition module arranged on the charging base; after the temperature of the charging base is determined to reach the preset temperature based on the fifth temperature data, first temperature data, which are sent by the wearable equipment and are measured in a first preset period, are received, and second temperature data, which are measured in the first preset period, of a temperature acquisition module arranged on the charging base are obtained.

The method further includes, after determining, based on the fifth temperature data, that the temperature of the charging base reaches the preset temperature, receiving first temperature data measured in a first preset period sent by the wearable device, and obtaining second temperature data measured in the first preset period by a temperature acquisition module provided in the charging base, where the charging base is further configured to: after the temperature of the charging base reaches a charging temperature peak value based on the fifth temperature data, controlling a heating module arranged on the charging base to heat the charging base; when the temperature of the charging base reaches the preset temperature, the heating module is controlled to stop heating the charging base.

The specific implementation manner of the temperature measurement function calibration system of the present application is substantially the same as that of each embodiment of the temperature measurement function calibration method described above, and will not be described herein.

In addition, the application also provides a temperature measurement function calibration device which is applied to the charging base and comprises:

The receiving module is used for receiving first temperature data which are sent by the wearable equipment and are measured in a first preset period when the wearable equipment is detected to have the function of calibrating temperature measurement, and obtaining second temperature data which are measured in the first preset period by the temperature acquisition module arranged on the charging base;

A first determination module for determining a temperature compensation value based on the first temperature data and the second temperature data;

and the sending module is used for sending the temperature compensation value to the wearable device so that the wearable device can calibrate the temperature measurement function of the wearable device based on the temperature compensation value.

Illustratively, the temperature measurement function calibration device further includes:

The acquisition module is used for acquiring third temperature data measured by the temperature acquisition module in a second preset period when effective contact with the wearable equipment is detected, and receiving fourth temperature data transmitted by the wearable equipment and measured in the second preset period;

The second determining module is used for determining a calibration judgment parameter based on the third temperature data and the fourth temperature data;

And the third determining module is used for determining that the wearable equipment needs to calibrate the temperature measurement function if the calibration judgment parameter is greater than or equal to a preset calibration judgment parameter threshold.

Illustratively, the temperature measurement function calibration device further includes:

The adjusting module is used for adjusting the preset calibration judgment parameter threshold value based on the temperature compensation value and the calibration judgment parameter to obtain an adjusted preset calibration judgment parameter threshold value;

And the judging module is used for judging through the adjusted preset calibration judgment parameter threshold value when judging the size between the calibration judgment parameter and the preset calibration judgment parameter threshold value next time.

Illustratively, the receiving module is further configured to:

When detecting that the wearable equipment needs to calibrate a temperature measurement function, charging the wearable equipment, and monitoring fifth temperature data acquired by a temperature acquisition module arranged on the charging base;

After the temperature of the charging base is determined to reach the preset temperature based on the fifth temperature data, first temperature data, which are sent by the wearable equipment and are measured in a first preset period, are received, and second temperature data, which are measured in the first preset period, of a temperature acquisition module arranged on the charging base are obtained.

Illustratively, the receiving module is further configured to:

After the temperature of the charging base reaches a charging temperature peak value based on the fifth temperature data, controlling a heating module arranged on the charging base to heat the charging base;

When the temperature of the charging base reaches the preset temperature, the heating module is controlled to stop heating the charging base.

The specific implementation manner of the temperature measurement function calibration device of the present application is substantially the same as that of each embodiment of the temperature measurement function calibration method described above, and will not be described herein.

In addition, the application also provides a charging base. As shown in fig. 5, fig. 5 is a schematic structural diagram of a hardware running environment according to an embodiment of the present application.

It should be noted that fig. 5 is a schematic structural diagram of a hardware operating environment of the charging base.

As shown in fig. 5, the charging base may include: a processor 5001, e.g., a CPU, memory 5005, user interface 5003, network interface 5004, communications bus 5002. Wherein a communication bus 5002 is employed for enabling connected communications between these components. The user interface 5003 may include a Display screen (Display), an input unit such as a Keyboard (Keyboard), and the optional user interface 5003 may also include a standard wired interface, a wireless interface. The network interface 5004 optionally may include a standard wired interface, a wireless interface (e.g., WI-FI interface). The memory 5005 may be a high-speed RAM memory or a stable memory (non-volatile memory), such as a disk memory. The memory 5005 may also optionally be a storage device separate from the aforementioned processor 5001.

Optionally, the charging dock may also include an RF (Radio Frequency) circuit, a sensor, an audio circuit, a WiFi module, and the like.

It will be appreciated by those skilled in the art that the charging base structure shown in fig. 5 is not limiting of the charging base and may include more or fewer components than shown, or may combine certain components, or a different arrangement of components.

As shown in fig. 5, an operating system, a network communication module, a user interface module, and a temperature measurement function calibration program may be included in the memory 5005 as one type of computer storage medium. The operating system is a program for managing and controlling the hardware and software resources of the charging base, and supports the operation of the temperature measurement function calibration program and other software or programs.

In the charging base shown in fig. 5, the user interface 5003 is mainly used for connecting a terminal, and performing data communication with the terminal, such as receiving a request sent by the terminal; the network interface 5004 is mainly used for a background server, and performs data communication with the background server; the processor 5001 may be configured to invoke the temperature measurement function calibration program stored in the memory 5005 and to perform the steps of the temperature measurement function calibration method as described above.

The specific implementation manner of the charging base is basically the same as that of each embodiment of the temperature measurement function calibration method, and is not repeated here.

In addition, the embodiment of the application also provides a computer readable storage medium, wherein the computer readable storage medium stores a temperature measurement function calibration program, and the temperature measurement function calibration program realizes the steps of the temperature measurement function calibration method when being executed by a processor.

The specific implementation manner of the computer readable storage medium of the present application is basically the same as that of each embodiment of the temperature measurement function calibration method, and will not be repeated here.

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 phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The foregoing embodiment numbers of the present application are merely for the purpose of description, and do not represent the advantages or disadvantages of the embodiments.

From the above description of the embodiments, it will be clear to those skilled in the art that the above-described embodiment method may be implemented by means of software plus a necessary general hardware platform, but of course may also be implemented by means of hardware, but in many cases the former is a preferred embodiment. Based on such understanding, the technical solution of the present application may be embodied essentially or in a part contributing to the prior art in the form of a software product stored in a storage medium (e.g. ROM/RAM, magnetic disk, optical disk) comprising instructions for causing a terminal device (which may be a mobile phone, a computer, a server, a device, or a network device, etc.) to perform the method according to the embodiments of the present application.

The foregoing description is only of the preferred embodiments of the present application, and is not intended to limit the scope of the application, but rather is intended to cover any equivalents of the structures or equivalent processes disclosed herein or in the alternative, which may be employed directly or indirectly in other related arts.

Claims (8)

1. A temperature measurement function calibration method, characterized by being applied to a charging base, the temperature measurement function calibration method comprising:

When detecting that the wearable device needs to calibrate a temperature measurement function, receiving first temperature data which are sent by the wearable device and are measured in a first preset period, and acquiring second temperature data which are measured in the first preset period by a temperature acquisition module arranged on the charging base, wherein the temperature data measured by the wearable device in the first preset period are stable near preset temperature, the second temperature data are stable at preset temperature, and the preset temperature is the environmental temperature of the working environment of the wearable device;

determining a temperature compensation value based on the first temperature data and the second temperature data;

Transmitting the temperature compensation value to the wearable device for the wearable device to calibrate a temperature measurement function of the wearable device based on the temperature compensation value;

When detecting that the wearable equipment needs to calibrate the temperature measurement function, the method comprises the steps of receiving first temperature data which are sent by the wearable equipment and are measured in a first preset period, and acquiring second temperature data which are measured in the first preset period by a temperature acquisition module of the charging base, wherein the second temperature data are provided with:

When effective contact with the wearable equipment is detected, acquiring third temperature data measured by the temperature acquisition module in a second preset period, and receiving fourth temperature data measured by the wearable equipment in the second preset period, wherein the temperature data corresponding to the second preset period is required to be stable;

Determining a calibration judgment parameter based on the third temperature data and the fourth temperature data;

If the calibration judgment parameter is greater than or equal to a preset calibration judgment parameter threshold, determining that the wearable equipment needs to calibrate a temperature measurement function;

the method further comprises the steps of:

based on the temperature compensation value and the calibration judgment parameter, adjusting the preset calibration judgment parameter threshold value to obtain an adjusted preset calibration judgment parameter threshold value;

and judging through the adjusted preset calibration judgment parameter threshold value when judging the magnitude between the calibration judgment parameter and the preset calibration judgment parameter threshold value next time.

2. The method of claim 1, wherein when detecting that the wearable device needs to calibrate the temperature measurement function, receiving first temperature data measured in a first preset period sent by the wearable device, and obtaining second temperature data measured in the first preset period by a temperature acquisition module disposed on the charging base, includes:

When detecting that the wearable equipment needs to calibrate a temperature measurement function, charging the wearable equipment, and monitoring fifth temperature data acquired by a temperature acquisition module arranged on the charging base;

After the temperature of the charging base is determined to reach the preset temperature based on the fifth temperature data, first temperature data, which are sent by the wearable equipment and are measured in a first preset period, are received, and second temperature data, which are measured in the first preset period, of a temperature acquisition module arranged on the charging base are obtained.

3. The method of claim 2, wherein after determining that the temperature of the charging base reaches the preset temperature based on the fifth temperature data, the steps of receiving first temperature data measured in a first preset period sent by the wearable device, and acquiring second temperature data measured in the first preset period by a temperature acquisition module disposed on the charging base include:

After the temperature of the charging base reaches a charging temperature peak value based on the fifth temperature data, controlling a heating module arranged on the charging base to heat the charging base;

When the temperature of the charging base reaches the preset temperature, the heating module is controlled to stop heating the charging base.

4. A charging base, characterized in that it comprises a heat-conducting member, a temperature acquisition module and a wireless communication module, said charging base being further capable of implementing the steps of the temperature measurement function calibration method according to any one of claims 1 to 3;

The heat conducting piece is fixedly connected with the temperature acquisition module and used for introducing heat of the wearable equipment when the heat conducting piece is in effective contact with the wearable equipment;

The temperature acquisition module is used for acquiring the temperature of the heat conducting piece so as to obtain the temperature of the charging base;

The wireless communication module is used for establishing communication connection with the wearable equipment so as to receive temperature data sent by the wearable equipment.

5. A temperature measurement function calibration system, the system comprising a wearable device and a charging base;

The wearable device is used for: when the temperature measurement function needs to be calibrated, first temperature data measured in a first preset period of time are sent to the charging base; receiving a temperature compensation value sent by the charging base, and calibrating the temperature measurement function based on the temperature compensation value; transmitting fourth temperature data measured in a second preset period to the charging base when the wearable device is in effective contact with the charging base;

The charging base is used for: when effective contact with the wearable equipment is detected, acquiring third temperature data measured by a temperature acquisition module in a second preset period, and receiving fourth temperature data measured in the second preset period and sent by the wearable equipment, wherein the temperature data corresponding to the second preset period is required to be stable; determining a calibration judgment parameter based on the third temperature data and the fourth temperature data; if the calibration judgment parameter is greater than or equal to a preset calibration judgment parameter threshold, determining that the wearable equipment needs to calibrate a temperature measurement function; when detecting that the wearable equipment needs to calibrate a temperature measurement function, receiving first temperature data which are sent by the wearable equipment and are measured in a first preset period, and acquiring second temperature data which are measured in the first preset period by a temperature acquisition module arranged on the charging base; wherein temperature data measured by the wearable device in a first preset period of time are stable near a preset temperature, second temperature data are stable at the preset temperature, the preset temperature is the ambient temperature of the working environment of the wearable device, a temperature compensation value is determined based on the first temperature data and the second temperature data, and the temperature compensation value is sent to the wearable device; the charging base is further configured to adjust the preset calibration judgment parameter threshold based on the temperature compensation value and the calibration judgment parameter, so as to obtain an adjusted preset calibration judgment parameter threshold; and judging through the adjusted preset calibration judgment parameter threshold value when judging the magnitude between the calibration judgment parameter and the preset calibration judgment parameter threshold value next time.

6. A temperature measurement function calibration device, characterized by being applied to a charging base, the temperature measurement function calibration device comprising:

The device comprises a receiving module, a temperature acquisition module and a temperature control module, wherein the receiving module is used for receiving first temperature data which are sent by the wearable device and are measured in a first preset period when detecting that the wearable device needs to calibrate a temperature measurement function, and acquiring second temperature data which are measured in the first preset period by the temperature acquisition module arranged on the charging base, wherein the temperature data measured by the wearable device in the first preset period are stable near preset temperature, the second temperature data are stable at the preset temperature, and the preset temperature is the environmental temperature of the working environment of the wearable device;

A first determination module for determining a temperature compensation value based on the first temperature data and the second temperature data;

a sending module, configured to send the temperature compensation value to the wearable device, so that the wearable device calibrates a temperature measurement function of the wearable device based on the temperature compensation value;

The acquisition module is used for acquiring third temperature data measured by the temperature acquisition module in a second preset period when effective contact with the wearable equipment is detected, and receiving fourth temperature data measured by the wearable equipment in the second preset period, wherein the temperature data corresponding to the second preset period is required to be stable;

The second determining module is used for determining a calibration judgment parameter based on the third temperature data and the fourth temperature data;

a third determining module, configured to determine that the wearable device needs to calibrate a temperature measurement function if the calibration determination parameter is greater than or equal to a preset calibration determination parameter threshold;

The adjusting module is used for adjusting the preset calibration judgment parameter threshold value based on the temperature compensation value and the calibration judgment parameter to obtain an adjusted preset calibration judgment parameter threshold value;

And the judging module is used for judging through the adjusted preset calibration judgment parameter threshold value when judging the size between the calibration judgment parameter and the preset calibration judgment parameter threshold value next time.

7. A charging base comprising a memory, a processor and a temperature measurement function calibration program stored on the memory and executable on the processor, which when executed by the processor implements the steps of the temperature measurement function calibration method of any one of claims 1 to 3.

8. A computer-readable storage medium, characterized in that it has stored thereon a temperature measurement function calibration program which, when executed by a processor, implements the steps of the temperature measurement function calibration method according to any one of claims 1 to 3.