JP6957402B2 - Body temperature measurement processing program, body temperature measurement device and body temperature measurement processing system equipped with this program - Google Patents

Description

The present invention relates to a body temperature measurement processing program for specifying body temperature by being worn on the body and measuring skin temperature and external temperature, a body temperature measuring device provided with this program, and a body temperature measuring processing system.

In recent years, there is an increasing need to measure body temperature for a long period of time such as while sleeping, exercising, or working for the purpose of health management. In order to measure body temperature, it is common to measure it in the mouth or under the armpit, but it is difficult to measure body temperature for a long time at these positions. As a method of measuring body temperature for a long time, a method of measuring body surface temperature (skin temperature) by attaching a device to the body is known, but since body surface temperature is easily affected by outside air temperature, outside air temperature It is necessary to correct the body surface temperature and calculate the body temperature. Therefore, it is desirable to calculate the body temperature with high accuracy even for a sudden temperature change of the external temperature.

Conventionally, various body temperature measuring devices for knowing the body temperature are known. For example, in Patent Document 1, as a body temperature information terminal device, a body surface temperature detection unit is provided on a surface of the casing on the body surface side so as to project from the casing, and an outside air temperature detection unit projects from the casing on the opposite surface. When specifying the body temperature as a representative temperature, the temperature is in a common sense range (for example, 33 ° C. to 38 ° C.) that is considered to be a daily body temperature with respect to the measured body surface temperature and the outside air temperature. ) Is removed, and the temperature data other than the removed temperature data is modified to the modified body surface temperature according to Fourier's law. It is described that the state is determined and used as a representative temperature candidate, and among the representative temperature candidates, the one having the highest temperature is specified as the representative temperature.

Japanese Patent No. 3909301

However, the one described in Patent Document 1 is the modified body surface temperature in which the body surface temperature is modified according to Fourier's law, and the thermal equilibrium state in which the temporal fluctuation range of a plurality of modified body surface temperatures is small is determined and is the highest as a representative temperature candidate. Since the temperature is specified as the representative temperature, the temperature when the external temperature suddenly changes is excluded when determining the thermal equilibrium state, and there is a limit to the accuracy of specifying the representative temperature as a whole. In addition, since the temperature is calculated as the representative temperature, there is a problem that the body temperature cannot be specified in real time.

Therefore, the present invention has been made in view of the above problems, and provides a body temperature measurement processing program for improving the accuracy of body temperature identification in response to a sudden temperature change of an external temperature, a body temperature measurement device provided with this program, and a body temperature measurement processing system. The purpose is to do.

In order to solve the above problem, in the invention of claim 1, it is measured every predetermined time by a skin temperature sensor that is attached to the body and measures the skin temperature and an external temperature sensor that measures the external temperature. A body temperature measurement processing program that specifies the body temperature from the skin temperature data and the external temperature data stored in the body temperature measuring device in which the skin temperature data and the external temperature data are stored in the storage means, and the stored skin temperature. Based on the data and the external temperature data, it is obtained from the means for erasing the temperature data until the predetermined time is reached, the skin temperature data and the external temperature data, the body temperature measuring device, and the thermal conductivity of the skin. The calculation is performed to specify the body temperature from the coefficient value to be obtained, and the body temperature measuring device and the skin with respect to the amount of change using the external temperature with respect to the skin temperature data and the external temperature data for each time other than the erased temperature data. From the relationship of the coefficient value obtained by the thermal conductivity of, specify and change the coefficient value according to the amount of change using the measured external temperature data, and change the changed coefficient value, the skin temperature data for each hour, and the outside. The configuration includes a means for correcting the skin temperature to obtain the body temperature using the temperature data.

In the invention of claim 2, the skin temperature data and the external temperature data measured at predetermined time intervals by the skin temperature sensor which is attached to the body and measures the skin temperature and the external temperature sensor which measures the external temperature are obtained. It is a body temperature measurement processing program that identifies the body temperature from the skin temperature data and the external temperature data stored in the body temperature measuring device stored in the storage means, and the stored skin temperature data and the external temperature data are input. , A means for erasing the temperature data until the predetermined time is reached among the skin temperature data, and at least the measured external temperature with respect to the skin temperature data and the external temperature data for each time other than the erased temperature data. It is determined whether or not the amount of change using the data is equal to or greater than a predetermined judgment value, and if the amount of change is less than the above judgment value, it is obtained from the skin temperature data, the external temperature data, the device, and the thermal conductivity of the skin. The skin temperature is corrected using the coefficient value to obtain the body temperature, and when the amount of change is equal to or more than the above-mentioned judgment value, the most recent skin temperature set to the body temperature below the above-mentioned judgment value is used as the body temperature. It is configured.

The invention of claim 3 is a body temperature measuring device that is worn on the body, measures the skin temperature and the external temperature, and specifies the body temperature based on at least the elapsed time and the measured temperature data, and is the skin temperature for measuring the skin temperature. A sensor, an external temperature sensor that measures the external temperature, at least a storage unit that stores the measured skin temperature data and the external temperature data in association with the elapsed measurement time, and at least the stored skin temperature. Of the data, the temperature data until the predetermined time is reached is erased, and the skin temperature data and the external temperature data and the device and the heat of the skin are compared with the skin temperature data and the external temperature data for each time other than the erased temperature data. The calculation is performed to specify the body temperature from the coefficient value obtained from the conductivity, and the measured external temperature data is obtained from the relationship between the coefficient value obtained from the device and the thermal conductivity of the skin with respect to the amount of change using the external temperature. Processed with a program that specifies and changes the coefficient value according to the amount of change used, corrects the skin temperature using the changed coefficient value, the skin temperature data for each hour, and the external temperature data to obtain the body temperature. It is configured to have a processing unit and a processing unit.

The invention of claim 4 is a body temperature measuring device that is worn on the body, measures the skin temperature and the external temperature, and specifies the body temperature based on at least the elapsed time and the measured temperature data, and is the skin temperature for measuring the skin temperature. A sensor, an external temperature sensor that measures the external temperature, at least a storage unit that stores the measured skin temperature data and the external temperature data in association with the elapsed measurement time, and at least the stored skin temperature. Of the data, the temperature data until the predetermined time is reached is erased, and the amount of change using at least the measured external temperature data with respect to the skin temperature data and the external temperature data for each time other than the erased temperature data is It is determined whether or not it is equal to or more than a predetermined judgment value, and if the amount of change is less than the above judgment value, the skin is used using the skin temperature data and the external temperature data and the coefficient value obtained from the thermal conductivity of the device and the skin. The body temperature is corrected to obtain the body temperature, and when the amount of change is equal to or more than the above-mentioned judgment value, the configuration includes a processing unit including a program for setting the latest skin temperature, which is the body temperature below the above-mentioned judgment value, as the body temperature. ..

The invention of claim 5 is a body temperature measurement processing system that measures the skin temperature and the external temperature of the body and specifies the body temperature based on at least the elapsed time and the measured temperature data, which is attached to the body and is the skin temperature. A body temperature measurement including a skin temperature sensor for measuring the external temperature, an external temperature sensor for measuring the external temperature, and at least a storage unit for storing the measured skin temperature data and the external temperature data in association with the elapsed measurement time. The skin temperature data and the external temperature data associated with the stored measurement elapsed time are acquired from the device and the body temperature measuring device, and at least the temperature of the acquired skin temperature data until a predetermined time is reached. The data is erased, and for the skin temperature data and the external temperature data for each time other than the erased temperature data, the skin temperature data and the external temperature data and the coefficient value obtained from the body temperature measuring device and the thermal conductivity of the skin are used. The calculation to specify the body temperature is performed from A processing unit that specifies and changes the corresponding coefficient value, and has a processing unit that provides and processes a program that corrects the skin temperature using the changed coefficient value, the skin temperature data for each hour, and the external temperature data to obtain the body temperature. It is configured to have a body temperature measurement processing device including the above.

The invention of claim 6 is a body temperature measurement processing system that measures the skin temperature and the external temperature of the body and specifies the body temperature based on at least the elapsed time and the measured temperature data, which is attached to the body and is the skin temperature. A body temperature measurement including a skin temperature sensor for measuring the external temperature, an external temperature sensor for measuring the external temperature, and at least a storage unit for storing the measured skin temperature data and the external temperature data in association with the elapsed measurement time. The skin temperature data and the external temperature data associated with the stored measurement elapsed time are acquired from the device and the body temperature measuring device, and at least the temperature of the acquired skin temperature data until a predetermined time is reached. The data is erased, and it is determined whether or not the amount of change using at least the measured external temperature data is equal to or more than a predetermined judgment value with respect to the skin temperature data and the external temperature data for each time other than the erased temperature data. If the amount of change is less than the above-mentioned judgment value, the skin temperature is corrected using the skin temperature data and the external temperature data and the coefficient value obtained from the thermal conductivity of the device and the skin to obtain the body temperature, and the amount of change is obtained. When is greater than or equal to the above-mentioned determination value, the configuration includes a processing unit including a program for setting the latest skin temperature, which is set to the body temperature below the above-mentioned determination value, and a body temperature measuring processing device including the above-mentioned determination value.

According to the inventions of claims 1, 3 and 5, in the processing of the program for specifying the body temperature, until the predetermined time is reached among the skin temperature data based on the skin temperature data and the external temperature data measured every hour. The temperature data is erased, and the body temperature is specified from the skin temperature data and external temperature data, the body temperature measuring device, and the coefficient value obtained from the thermal conductivity of the skin. From the relationship between the skin temperature data and the external temperature data of the above, the coefficient value obtained by the device and the thermal conductivity of the skin with respect to the amount of change using the external temperature, the relationship according to the amount of change using the measured external temperature data. By specifying and changing the numerical value and correcting the skin temperature using the changed coefficient value, the skin temperature data for each hour, and the external temperature data to obtain the body temperature, the external temperature suddenly changes. Even in this case, the body temperature can be accurately specified by changing the coefficient value.

According to the inventions of claims 2, 4 and 6, in the processing of the program for specifying the body temperature, among the skin temperature data measured every hour, the temperature data until the predetermined time is reached is erased, and the erased temperature is obtained. For skin temperature data and external temperature data for each time other than the data, it is determined whether or not the amount of change using at least the measured external temperature data is equal to or greater than the predetermined judgment value, and when the amount of change is less than the judgment value. Is the body temperature corrected by using the skin temperature data and external temperature data and the coefficient value obtained from the device and the thermal conductivity of the skin, and if the amount of change is greater than or equal to the judgment value, it is less than the judgment value. By configuring the body temperature to be the latest skin temperature, which is the body temperature, when the external temperature changes suddenly, the body temperature at that time is replaced with the latest body temperature when the temperature change is small, and the predetermined time range It is possible to accurately identify the body temperature in Japan.

It is a block diagram of the body temperature measuring apparatus which concerns on this invention. It is a block block diagram of the electronic circuit in the body temperature measuring apparatus and the body temperature measuring processing apparatus which concerns on this invention. It is explanatory drawing of the relationship between the wearing state of the body temperature measuring apparatus of FIG. 1 and the law of Fourier. It is explanatory drawing of the coefficient value specification used in the law of Fourier processed by the body temperature measurement processing program. It is explanatory drawing of the skin temperature corresponding to the change of the external temperature and the corrected skin temperature with respect to the external temperature. It is a processing flowchart (1) of the 1st Embodiment of the body temperature measurement processing program which specifies a body temperature. It is a processing flowchart (2) of the 1st Embodiment of the body temperature measurement processing program which specifies a body temperature. It is explanatory drawing of the corrected skin temperature by changing the coefficient value used in Fourier's law. It is explanatory drawing of the corrected skin temperature in the case of constant coefficient value and the case of changing the coefficient value of FIG. It is a processing flowchart of the coefficient value change for each change amount using an external temperature in another example of FIG. It is explanatory drawing of the coefficient value which changes for each change amount in FIG. 10 is an explanatory diagram of a corrected skin temperature by changing a coefficient value used in Fourier's law in FIGS. 10 and 11. It is a processing flowchart (1) of the 2nd Embodiment of the body temperature measurement processing program which specifies a body temperature. It is a processing flowchart (2) of the 2nd Embodiment of the body temperature measurement processing program which specifies a body temperature. It is explanatory drawing of body temperature specific in 2nd Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. This embodiment will be described as a system of the body temperature measurement processing device and the body temperature measurement processing device, assuming that the body temperature measurement processing device is provided with the body temperature measurement processing program, but the body temperature measurement processing device is provided with the body temperature measurement processing device. It may be (described later).

FIG. 1 shows a block diagram of the body temperature measuring device according to the present invention, and FIG. 2 shows a block configuration diagram of an electronic circuit in the body temperature measuring device and the body temperature measuring processing device according to the present invention. In FIGS. 1A and 1B, the body temperature measuring device 11 is attached to the body, and the skin-side casing is used as the skin-side housing surface 13 in which one surface of the housing 12 is in direct contact with the skin. The tip portion thereof is exposed at a predetermined height from the skin temperature sensor hole 15 formed at the corresponding position on the body surface 13, and the tip portion comes into contact with the skin to measure the skin temperature. The configuration of the tip position of the body temperature measuring device 11 shown in the present embodiment, particularly the skin temperature sensor 21, is an example and may be the same as the configuration of the previously known body temperature measuring device.

Further, a surface other than the skin-side housing surface 13, where the external temperature sensor 22 for measuring the external temperature is located at a predetermined position on the outer-side housing surface 14 on the opposite surface. In the figure, the tip portion of the hole 16 for the external temperature sensor is exposed and located on the inner side of the housing 12, and a gap region 22A is provided between the position of the surface 14 of the outer housing and the tip portion. The external temperature (temperature inside clothes) is measured, but the configuration of the tip position is an example, and as is known from the past, a body temperature measuring device that is flush with the surface or protrudes from the surface. It may be the same as the configuration of.

As shown in FIG. 1C, an electronic circuit board 31A on which the electronic circuit 31 is mounted is provided inside the housing 12, and is located on the skin side housing surface 13 side of the electronic circuit board 31A. The skin temperature sensor 21 is mounted, and the external temperature sensor 22 is mounted on the outer housing surface 14 side.

As shown in FIG. 2, the above-mentioned body temperature measuring device 11 constitutes one of the body temperature measuring processing systems, and can communicate freely with the body temperature measuring processing device 41 constituting the other of the systems regardless of whether it is wired or wireless. (Here, it is wireless).

The electronic circuit 31 included in the body temperature measuring device 11 includes a processing unit 51, a timing unit 52, a storage unit 53, a transmission unit 54, and an operation input unit 55. Here, the time measuring unit 52 is a circuit having a calendar function and counting the date and time, the storage unit 53 is a memory mainly for storing each temperature data, and the transmitting unit 54 is used in the body temperature measuring processing device 41. For example, it is a communication interface for transmitting data by BLUETOOTH (registered trademark) or the like, and the operation input unit 55 is a circuit for inputting an operation signal from an operation unit (not shown in FIG. 1).

The processing unit 51 inputs time data from the measuring unit 52 in response to the measurement start signal from the operation input unit 55, and sets in advance from the skin temperature sensor 21 and the external temperature sensor 22 shown in FIG. 1 (by the measurer). The skin temperature data and the external temperature data measured at predetermined time intervals are input, and the temperature data of the skin temperature data and the external temperature data for each passage of time are associated with the elapsed time and stored in the storage unit 53. A program is provided which performs a process of transmitting the temperature data stored in the storage unit 53 to the body temperature measurement processing device 41 via the transmission unit 54 at an appropriate timing operation by the measurer.

The body temperature measurement processing device 41 includes at least a processing unit 61, a receiving unit 62, a storage unit 63, and a display unit 64. The body temperature measurement processing device 41 is, for example, a mobile terminal such as a smartphone, a personal computer, or the like, and the above-mentioned body temperature measurement processing program is installed and appropriately executed. Here, the body temperature measurement processing function is specialized. It is explained as.

The processing unit 61 includes a body temperature measurement processing program, and the processing content will be described with reference to FIG. The receiving unit 62 is a communication interface for receiving data having the same communication protocol as the transmitting unit 54 of the body temperature measuring device 11, and the storage unit 63 stores the temperature data acquired from the body temperature measuring device 11 and identifies the body temperature. Is stored in association with the measurement date, and also serves as a program processing area for specifying the body temperature. The display unit 64 is a display of a mobile terminal or a computer, and here, it is intended to display a transition of a body temperature within a predetermined period range specified specifically for the present invention.

Here, FIG. 3 shows an explanatory diagram of the relationship between the wearing state of the body temperature measuring device of FIG. 1 and Fourier's law, and FIG. 4 shows specifying the coefficient value used in Fourier's law processed by the body temperature measuring processing program. An explanatory diagram is shown. In FIG. 3A, the body temperature measuring device 11 is worn between the body, for example, the skin 71 and clothing 72 such as underwear. In this case, the skin temperature sensor 21 in the body temperature measuring device 11 directly contacts the skin 71 to measure the skin temperature, and the external temperature sensor 22 measures the external temperature (the temperature inside the clothes) on the clothing 72 side.

Therefore, the calculation will be described with reference to FIG. 3 (B) in order to calculate the body temperature from the skin temperature. Here, the corrected skin temperature (body temperature) is Ti, the coefficient value obtained from the body temperature measuring device and the heat conductivity of the skin is K, the skin temperature is Ts, and the external temperature is Ta. The heat conductivity from 71A to the skin temperature sensor 21 is λ1, and the heat conductivity from the skin 71 to the external temperature sensor 22 is λ2.

Therefore, when the heat flux (q) is applied to the body temperature measuring device 11 by using Fourier's law (q = λ (dt / dx)) that the heat flux (q) is proportional to the temperature gradient (dt / dx) and the thermal conductivity λ,
From q = λ1 (Ti-Ts), q = λ2 (Ts-Ta) to Ti = Ts + K (Ts-Ta) (Equation 1)
(K is a coefficient value obtained from the body temperature measuring device and the thermal conductivity of the skin, and K = λ2 / λ1)
The corrected skin temperature Ti is derived by the formula of.

The coefficient value K obtained from the above-mentioned body temperature measuring device and the thermal conductivity of the skin can be determined by experience as the best value (there is almost no physical difference) in the relationship between the body temperature measuring device and the body, but it is calculated. It can also be calculated by. For example, in a relationship graph using the skin temperature, the external temperature, and the temperature difference between the skin temperature and the external temperature, the approximate curve (linear curve) when different temperatures are used for the x-axis and the y-axis. It can be calculated in relation to the above (Equation 1). For example, if the slope of the approximate curve (linear curve) when the x-axis is the external temperature and the y-axis is the skin temperature is α and the intercept is β, then (Equation 1) is Ts = αTa + β (Equation 2). By changing to, α = K / (1 + K), which can be calculated as K = α / (1-α).

As an example, as a method of calculating the amount of temperature change for 1 minute, it may be calculated from the temperature difference x minutes before (for example, 8 minutes before), the skin temperature is (Equation 3), and the external temperature is (Equation 4). , The skin-external temperature difference can be calculated using (Equation 5).
{Ts (n) -Ts (n-x)} / x (Equation 3)
{Ta (n) -Ta (n-x)} / x (Equation 4)
[{Ts (n) -Ta (n)}-{Ts (n-x) -Ta (n-x)}] / x (Equation 5)
In this case, Ta (n) is the external temperature at a certain point in time, Ts (n) is the skin temperature at a certain point in time, x is the interval for calculating the temperature difference, and Ta (n−x) is x minutes before the certain point in time. The external temperature, Ts (n), is the skin temperature x minutes before a certain point in time. The x can be arbitrarily determined depending on the performance of the body temperature measuring device, but is determined in 1 to 60 minutes, preferably 1 to 30 minutes, and more preferably 2 to 10 minutes. If the interval is short, even the part where the temperature is changing can be seen only in a minute range, so it is estimated that there is no change. Further, if the interval is long and the temperature changes in a short time, the temperature happens to be the same and cannot be excluded.

On the other hand, in order to experimentally determine the relationship between the coefficient value K and the amount of temperature change, the skin temperature and the outside temperature under a constant outside air temperature and when the outside air temperature is suddenly changed are measured, and the body temperature under a constant outside air temperature is measured. The body temperature (corrected skin temperature) when the outside air temperature is suddenly changed by changing the coefficient value K is corrected so that the temperature becomes the same as the (corrected skin temperature). The relationship between the coefficient value K at this time and the above temperature change amount is obtained as shown in FIG. 4, and the ideal coefficient value K with respect to the temperature change amount can be calculated from this approximate curve.

When calculating the relationship between the coefficient value K and the amount of temperature change, it may be calculated for each body temperature measuring device or measurer, or it may be a program for calculating the coefficient value K for each measurement, and the coefficient value K is the body temperature measurement. Since it is largely derived from the structure of the device, there is no problem even if the coefficient value K calculated in advance by a certain subject is used. In this case, since the coefficient value K is preferably calculated under a constant body temperature, it is preferable to calculate the coefficient value K in a short time at rest when awake.

Therefore, FIG. 5 shows an explanatory diagram of the skin temperature according to the change in the external temperature and the corrected skin temperature with respect to the external temperature. In FIG. 5A, the measurer wears the body temperature measuring device 11, and the environmental pattern A (wearing downwear and the temperature of the outside air is 8 to 10 ° C.) and the environmental pattern B (wearing the downwear and the temperature of the outside air are high). 23 ° C.), the skin temperature and the outside air temperature measured when the environment pattern C (the temperature of the outside air is 23 ° C. while wearing work clothes) is shown. The measurer wears the body temperature measuring device 11, and for example, the skin temperature data and the external temperature data for 30 minutes after the wearing are deleted until the skin temperature is followed.

Then, the body temperature (corrected skin temperature) calculated by using the above-mentioned Fourier's law of (Equation 1) is shown in FIG. 5 (B). In this case, the above-mentioned coefficient value K is a body temperature calculated with the calculated coefficient value K being constant under any environmental pattern. This calculated body temperature serves as a reference comparison target (Ref) for the body temperature specifying process by the body temperature measurement processing program in the present invention.

Next, FIGS. 6 and 7 show a processing flowchart of the first embodiment of the body temperature measurement processing program for specifying the body temperature, and FIG. 8 shows an explanatory diagram of the corrected skin temperature by changing the coefficient value used in Fourier's law. , FIG. 9 shows an explanatory diagram of the corrected skin temperature when the coefficient value of FIG. 8 is constant and when the coefficient value is changed.

The body temperature measurement processing program of the first embodiment in the present invention is provided in the processing unit 61 of the temperature measurement processing apparatus 41 of FIG. 2, and as a main means of program processing, the skin is based on skin temperature data and external temperature data. Of the temperature data, a means for erasing the temperature data until the predetermined time is reached (referred to as the first means), skin temperature data, external temperature data, a body temperature measuring device, and a coefficient value obtained from the thermal conductivity of the skin. As a calculation to specify the body temperature from, the skin temperature data and the external temperature data for each time other than the erased temperature data are obtained by the body temperature measuring device and the thermal conductivity of the skin with respect to the amount of change using the external temperature. From the relationship of the coefficient values to be obtained, the coefficient value according to the amount of change using the measured external temperature data is specified and changed, and the changed coefficient value, the skin temperature data for each hour, and the external temperature data are used. It is provided with a means (as a second means) for correcting the skin temperature to obtain the body temperature. The amount of change using the external temperature data in this case is the amount of change in the temperature difference between the skin temperature and the external temperature and the amount of change in the external temperature, and either of them may be targeted and is appropriately selected.

Specifically, first, in FIG. 6A, the body temperature measuring processing device 41 acquires the skin temperature data and the external temperature data associated with the elapsed time from the body temperature measuring device 11 and stores them in the storage unit 63 ( Step 1 (S1)). Subsequently, with respect to the acquired skin temperature data and external temperature data, the temperature data (skin temperature data and external temperature data) until the predetermined time is reached among the skin temperature data are deleted (S2). The temperature data until the predetermined time is reached is, for example, the temperature data until the skin temperature is followed, for example, the temperature data for 30 minutes immediately after the start is erased.

Therefore, it is determined whether or not the amount of change in the external temperature other than the erased temperature data is, for example, + 0.1 ° C./min or more (referred to as the first determination value) (S3A). Alternatively, as shown in FIG. 6B, it is determined whether or not the amount of change in the temperature difference between the skin temperature and the external temperature is, for example, −0.1 ° C./min or less (referred to as the second determination value). (S3B). The amount of change in the external temperature is calculated by the above (Equation 4), and the amount of change in the temperature difference between the skin temperature and the external temperature is calculated by the above (Equation 5).

When the amount of change in the external temperature is less than + 0.1 ° C./min, or the amount of change in the temperature difference between the skin temperature and the external temperature exceeds -0.1 ° C./min (S3A, S3B), the figure. As shown in 6 (C), the skin temperature data other than the erased temperature data, the external temperature data, the body temperature measuring device, and the coefficient value K obtained from the thermal conductivity of the skin are used to obtain the skin temperature data using Fourier's law. It is corrected and specified as body temperature (S4). This coefficient value K is the value used in FIG. 5 (B) described above.

On the other hand, when the amount of change in the external temperature is + 0.1 ° C./min or more, or the amount of change in the temperature difference between the skin temperature and the external temperature is -0.1 ° C./min or less (S3A, S3B). , As shown in FIG. 6 (D), the coefficient value K obtained from the skin temperature data other than the erased temperature data, the external temperature data, the body temperature measuring device, and the thermal conductivity of the skin is changed to the coefficient value K1 to Fourier. The skin temperature data is corrected using the above law and specified as the body temperature (S5).

The coefficient value K1 is a multiple (N) of the coefficient value K. The multiple N may be calculated for each structure of the body temperature measuring device. Referring to FIG. 4, when the amount of change in the external temperature is 0.1 or more, the coefficient value K is 1.8 or more, and when the amount of change in the external temperature is 0 (K = 0.8671 approximate curve section). Since it is more than doubled, N uses a numerical value of 2 to 5 (for example, N = 3).

As described above, a table when the coefficient value K when specifying the body temperature using Fourier's law is changed to the coefficient value K1 is shown in FIG. 8, and the specified body temperature (corrected skin temperature) at that time is shown in FIG. A comparison is shown in FIGS. 9 (A) and 9 (B). That is, FIG. 9 (A) is a diagram in which the body temperature (corrected skin temperature) calculated with the coefficient value K of FIG. 5 (B) being constant is rearranged in ascending order of the external temperature, and is changed to the coefficient value K1. Comparing the body temperature (corrected skin temperature) of 9 (B) with that of FIG. 9 (A), it is clear that the standard deviation σ is small, and the body temperature can be accurately specified even for a sudden change in the external temperature. Can be recognized.

Further, as an example, when the representative body temperature of one day is calculated from the measurement result for a long time such as the basal body temperature during bedtime, the specified body temperature (corrected skin temperature) is shown in FIG. 7 (A). On the other hand, the temperature data obtained by calculating the average value of the predetermined time range (measured time range) is specified as the body temperature (representative temperature) of the day (S6A). Alternatively, as shown in FIG. 7B, the temperature data obtained by calculating an approximate value of a predetermined time range (measured time range) with respect to the specified body temperature (corrected skin temperature) is used as the body temperature (representative temperature) of the day. Identify (S6B). That is, the average value (ave) or an approximate value of the body temperature (corrected skin temperature) for each time corrected based on the skin temperature data and the external temperature data of FIG. 5 (A) is calculated, and the body temperature (representative temperature) of the day is calculated. Identify as. By performing the process of determining the coefficient value K1 in advance, the subsequent processes can be performed in real time. Therefore, after the skin temperature follows the body temperature (for example, 30 minutes), the body temperature is measured at each measurement interval. Can be displayed.

The temperature data of the specified body temperature (representative temperature) is associated with the date of the measurement date and stored in the storage unit 63 (S7). Then, in the body temperature measurement processing device 41, according to an operation (not shown), the stored body temperature data of the body temperature is read out within a predetermined period range, displayed, and displayed on the display unit 64 (S8). For example, 30 days is designated as a predetermined period range, and the body temperature data for the 30 days is displayed as a graph and displayed on the display unit 64. This makes it possible to recognize the body temperature fluctuation of the measurer.

Next, FIG. 10 shows a flowchart for processing the coefficient value change for each change amount using the external temperature in another example of FIG. 6, and FIG. 11 shows an explanatory diagram of the coefficient value to be changed for each change amount in FIG. 12 shows an explanatory diagram of the corrected skin temperature by changing the coefficient value used in Fourier's law in FIGS. 10 and 11.

In the body temperature measurement processing program shown in FIGS. 10A and 10B, the second means of the body temperature measurement processing program shown in FIG. 6 is a change amount using an external temperature (temperature difference between the skin temperature and the external temperature). From the relationship of the coefficient value obtained by the body temperature measuring device and the thermal conductivity of the skin with respect to (the amount of change in the external temperature or the amount of change in the external temperature) in FIG. 4, the skin temperature for each time other than the temperature data erased by the first means With respect to the data and the external temperature data, at least for each change amount of the change amount using the external temperature data, the relevant coefficient value obtained from the heat conductivity of the body temperature measuring device and the skin with respect to the change amount using the external temperature. The coefficient value Kx according to the amount of change is specified, and the skin temperature is corrected to obtain the body temperature by using the specified coefficient value Kx, the skin temperature data for each hour, and the external temperature data.

That is, in FIG. 10A, the body temperature measurement processing device 41 acquires skin temperature data and external temperature data associated with the elapsed time from the body temperature measurement device 11 and stores them in the storage unit 63 (S11). Subsequently, with respect to the acquired skin temperature data and external temperature data, the temperature data (skin temperature data and external temperature data) until a predetermined time (for example, 30 minutes) is reached among the skin temperature data is deleted (skin temperature data and external temperature data). S12), this process is the same as in FIG. 6 (A) described above.

Therefore, the amount of change (the temperature between the skin temperature and the external temperature) using the external temperature data is the coefficient value obtained from the skin temperature data other than the erased temperature data, the external temperature data, the body temperature measuring device, and the thermal conductivity of the skin. Based on the change in the coefficient value obtained from the thermal conductivity of the device and the skin with respect to the amount of change in the difference or the amount of change in the external temperature), the Kx value is calculated for each measured amount of change in the external temperature, and Fourier's law The skin temperature data is corrected using and specified as the body temperature (S13A). Alternatively, as shown in FIG. 10B, the Kx value is calculated for each change in the temperature difference between the skin temperature and the external temperature, and the skin temperature data is corrected using Fourier's law to specify the body temperature. (S13B).

Here, for the change in the coefficient value according to the amount of change using the external temperature, the corrected skin temperature (body temperature) calculated in FIG. 5B is arranged in ascending order of the external temperature as shown in FIG. Obtained from the approximate curve of the relationship between the linear curve of the average value or the approximate value when changed and the coefficient value K when the temperature is constant with respect to the temperature change of the external temperature for 1 minute shown in FIG. Be done. These approximate curves may be acquired in advance, or may be measured and set by the measurer at the initial stage of the body temperature measuring device 11. By performing the process of determining the coefficient value Kx in advance, the subsequent processes can be performed in real time. Therefore, after the skin temperature follows the body temperature (for example, 30 minutes), the body temperature is measured at each measurement interval. Can be displayed.

That is, the coefficient value Kx for the temperature change in FIG. 4 is calculated for each acquired external temperature change amount so as to be the average value or an approximate value in FIG. 11, and the calculated coefficient value Kx is used to calculate the Fourier law. The skin temperature is corrected by the above and specified as the body temperature.

Tables and graphs of the specified body temperature (corrected skin temperature) at this time are shown in FIGS. 12 (A) and 12 (B). That is, the body temperature (corrected skin temperature) calculated with the coefficient value K in FIG. 9 (A) being constant is compared with the body temperature (corrected skin temperature) when the coefficient value K x shown in FIG. 12 (B) is changed. Therefore, it can be recognized that the standard deviation σ is clearly small and the body temperature is accurately specified even for a sudden change in the external temperature.

In this way, even when the external temperature suddenly changes, the body temperature can be accurately specified by changing the coefficient value.

Next, FIGS. 13 and 14 show a processing flowchart of the second embodiment of the body temperature measurement processing program for specifying the body temperature, and FIG. 15 shows an explanatory diagram of the body temperature specification in the second embodiment.

The body temperature measurement processing program of the second embodiment in the present invention is provided in the processing unit 61 of the temperature measurement processing apparatus 41 of FIG. 2, and as a main means of program processing, the skin is based on skin temperature data and external temperature data. Of the temperature data, at least the means for erasing the temperature data until the predetermined time is reached (referred to as the first means), the skin temperature data for each time other than the erased temperature data, and the external temperature data are measured. It is determined whether or not the amount of change is equal to or greater than the predetermined judgment value using the external temperature data, and if the amount of change is less than the above judgment value, the skin temperature data and the external temperature data and the thermal conductivity of the device and the skin are determined. The skin temperature is corrected using the coefficient value obtained from the above to obtain the body temperature, and when the amount of change is equal to or more than the above judgment value, the most recent skin temperature set to the body temperature below the above judgment value is used as the body temperature. (As a second means). The amount of change using the external temperature data in this case is the amount of change in the temperature difference between the skin temperature and the external temperature and the amount of change in the external temperature, and either of them may be targeted and is appropriately selected.

Specifically, first, in FIG. 13A, the body temperature measuring processing device 41 acquires the skin temperature data and the external temperature data associated with the elapsed time from the body temperature measuring device 11 and stores them in the storage unit 63 ( S21)). Subsequently, with respect to the acquired skin temperature data and external temperature data, the temperature data (skin temperature data and external temperature data) is set until the skin temperature is followed until a predetermined time (for example, 30 minutes) is reached among the skin temperature data. ) Is deleted (S22).

Then, from the skin temperature data other than the erased temperature data, the external temperature data, and the coefficient value K obtained from the body temperature measuring device and the thermal conductivity of the skin, the skin temperature data is obtained by using Fourier's law according to the above (Equation 1). Is corrected (S23).

Therefore, it is determined whether or not there is a temperature at which the absolute value of the amount of change in the external temperature other than the erased temperature data is, for example, 0.1 ° C./min or more (referred to as the third determination value) (S24A). Alternatively, as shown in FIG. 13B, it is determined whether or not the absolute value of the amount of change in the temperature difference between the skin temperature and the external temperature is, for example, 0.1 ° C./min or more (referred to as the fourth determination value). (S24B). The amount of change in the external temperature is calculated by (Equation 4), and the amount of change in the temperature difference between the skin temperature and the external temperature is calculated by (Equation 5).

When the absolute value of the amount of change in the external temperature is 0.1 ° C./min or more (S24A), as shown in FIG. 13 (C), the corresponding body temperature (corrected skin temperature) is set to the latest change in the external temperature. A temperature at which the absolute value of the amount is less than 0.1 ° C. is specified as a body temperature (S25A). When the absolute value of the amount of change in the temperature difference between the skin temperature and the external temperature is 0.1 ° C./min or more (S24B), as shown in FIG. 13 (D), the corresponding body temperature (corrected skin temperature). ) Is the temperature at which the absolute value of the amount of change in the temperature difference between the latest skin temperature and the external temperature is less than 0.1 ° C., and is specified as the body temperature (S25B).

Further, as an example, when the representative body temperature of one day is calculated from the measurement result for a long time such as the basal body temperature during bedtime, the specified body temperature (corrected skin temperature) is shown in FIG. 14 (A). On the other hand, the temperature data obtained by calculating the average value of the predetermined time range (measured time range) is specified as the body temperature (representative temperature) of the day (S26A). Alternatively, as shown in FIG. 14 (B), the temperature data obtained by calculating an approximate value of a predetermined time range (measured time range) with respect to the specified body temperature (corrected skin temperature) is used as the body temperature (representative temperature) of the day. Identify (S26B). That is, the average value (ave) or an approximate value of the body temperature (corrected skin temperature) for each time corrected based on the skin temperature data and the external temperature data of FIG. 5 (A) is calculated, and the body temperature (representative temperature) of the day is calculated. Identify as. It should be noted that by performing the process of determining the absolute value of the amount of change in the external temperature (for example, 0.1 ° C./min or more), which is the reference, in advance, the subsequent process can be performed in real time. After the temperature follows the body temperature (for example, 30 minutes), the body temperature can be displayed at each measurement interval.

The temperature data of the specified body temperature (representative temperature) is associated with the date of the measurement date and stored in the storage unit 63 (S27). Then, in the body temperature measurement processing device 41, according to an operation (not shown), the stored body temperature data of the body temperature is read out within a predetermined period range, displayed, and displayed on the display unit 64 (S28). For example, 30 days is designated as a predetermined period range, and the body temperature data for the 30 days is displayed as a graph and displayed on the display unit 64. This makes it possible to recognize the body temperature fluctuation of the measurer.

By the way, in FIGS. 13A and 13B described above, the third judgment value is defined as the absolute value of the amount of change in the external temperature of 0.1 ° C./min or more, or the fourth judgment value is defined as the skin temperature. The absolute value of the amount of change in the temperature difference from the external temperature was set to 0.1 ° C / min or more, but by setting each absolute value to 0.04 ° C / min, the specified body temperature (corrected skin temperature) The amount of change in the above is small, and the variation can be reduced.

Tables and graphs of body temperature (corrected skin temperature) specified by the above treatments S25A and 25B are shown in FIGS. 15A and 15B. That is, the standard deviation σ is clearly smaller than the body temperature (corrected skin temperature) calculated with the coefficient value K in FIG. 9 (A) constant, and the body temperature can be accurately adjusted even with a sudden change in the external temperature. It can be recognized that the identification has been made.

In this way, even when the external temperature suddenly changes, the body temperature can be accurately specified by changing the coefficient value.

By the way, the body temperature measurement processing program according to the present invention may be stored in a storage medium such as an optical disk, or may be freely downloaded using a net such as the Internet as a medium.

Further, since the body temperature can be accurately specified by the simple arithmetic processing by the body temperature measurement processing program, the body temperature measurement processing apparatus 41 is provided with the processing program of S8 in FIG. 7 or S28 in FIG. The body temperature measuring device 11 may be provided with a body temperature measuring processing program of another means. Further, the body temperature measuring device 11 may be provided with a display unit and provided with a body temperature measuring processing program that performs all the processing of FIGS. 6, 7, 13, and 14.

The body temperature measurement processing program of the present invention, a body temperature measuring device provided with this program, and a body temperature measuring processing system are manufactured, sold, used, etc. It can be used in the industrial field.

11 Body temperature measuring device 12 Housing 13 Skin side housing surface 14 External housing surface 15 Skin temperature sensor hole 16 External temperature sensor hole 21 Skin temperature sensor 22 External temperature sensor 22A Void area 31 Electronic circuit 31A Electronic circuit board 41 Body temperature measurement processing device 51, 61 Processing unit 52 Measuring unit 53, 63 Storage unit 54 Transmission unit 55 Operation input unit 62 Reception unit 64 Display unit 71 Skin 71A Deep body 72 Clothing

Claims (6)

Body temperature that is attached to the body and measures the skin temperature, and the skin temperature data and the external temperature data measured at predetermined time intervals by the external temperature sensor that measures the external temperature are stored in the storage means. A body temperature measurement processing program that identifies body temperature from the skin temperature data and external temperature data stored in the measuring device.
A means for erasing the temperature data until a predetermined time is reached among the skin temperature data based on the stored skin temperature data and the external temperature data.
The calculation is performed to specify the body temperature from the skin temperature data and the external temperature data and the coefficient value obtained from the body temperature measuring device and the thermal conductivity of the skin. From the relationship between the external temperature data and the coefficient value obtained from the above-mentioned body temperature measuring device and the thermal conductivity of the skin with respect to the amount of change using the external temperature, the coefficient value corresponding to the amount of change using the measured external temperature data is calculated. A means of specifying and changing the skin temperature and correcting the skin temperature using the changed coefficient value, the skin temperature data for each hour, and the external temperature data to obtain the body temperature.
A body temperature measurement processing program characterized by including. Body temperature that is attached to the body and measures the skin temperature, and the skin temperature data and the external temperature data measured at predetermined time intervals by the external temperature sensor that measures the external temperature are stored in the storage means. A body temperature measurement processing program that identifies body temperature from the skin temperature data and external temperature data stored in the measuring device.
A means for inputting the stored skin temperature data and external temperature data and erasing the temperature data of the skin temperature data until a predetermined time is reached.
With respect to the skin temperature data and the external temperature data for each time other than the erased temperature data, it is determined whether or not the amount of change using at least the measured external temperature data is equal to or greater than a predetermined judgment value, and the amount of change is determined. If is less than the above-mentioned judgment value, the skin temperature is corrected to obtain the body temperature by using the skin temperature data and the external temperature data and the coefficient value obtained from the thermal conductivity of the device and the skin, and the amount of change is the above-mentioned judgment value. In the above cases, a means for setting the latest skin temperature, which is set to the body temperature below the above judgment value, as the body temperature, and
A body temperature measurement processing program characterized by including. A body temperature measuring device that is worn on the body, measures skin temperature and external temperature, and specifies body temperature based on at least elapsed time and measured temperature data.
A skin temperature sensor that measures the skin temperature,
An external temperature sensor that measures the external temperature and
At least, a storage unit that stores the measured skin temperature data and external temperature data in association with the elapsed measurement time.
At least, among the stored skin temperature data, the temperature data until the predetermined time is reached is erased, and the skin temperature data and the external temperature data are obtained with respect to the skin temperature data and the external temperature data for each time other than the erased temperature data. The calculation is performed to specify the body temperature from the external temperature data and the coefficient value obtained from the thermal conductivity of the device and the skin. The relationship between the coefficient value obtained by the thermal conductivity of the device and the skin with respect to the amount of change using the external temperature. From, the coefficient value according to the amount of change using the measured external temperature data is specified and changed, and the skin temperature is corrected using the changed coefficient value, the skin temperature data for each hour, and the external temperature data. A processing unit that has a program to heat the body and processes it.
A body temperature measuring device comprising a body temperature measuring processing program. A body temperature measuring device that is worn on the body, measures skin temperature and external temperature, and specifies body temperature based on at least elapsed time and measured temperature data.
A skin temperature sensor that measures the skin temperature,
An external temperature sensor that measures the external temperature and
At least, a storage unit that stores the measured skin temperature data and external temperature data in association with the elapsed measurement time.
At least, among the stored skin temperature data, the temperature data until the predetermined time was reached was erased, and at least the skin temperature data and the external temperature data were measured for each time other than the erased temperature data. It is determined whether or not the amount of change using the external temperature data is equal to or greater than the predetermined judgment value, and if the amount of change is less than the above judgment value, the skin temperature data and the external temperature data and the thermal conductivity of the device and the skin are used. A program is provided in which the skin temperature is corrected using the obtained coefficient value to obtain the body temperature, and when the amount of change is equal to or more than the above judgment value, the latest skin temperature set to the body temperature below the above judgment value is used as the body temperature. Processing unit and
A body temperature measuring device comprising a body temperature measuring processing program comprising. A body temperature measurement processing system that measures the skin temperature and external temperature of the body and specifies the body temperature based on at least the elapsed time and the measured temperature data.
A skin temperature sensor that is worn on the body and measures the skin temperature, an external temperature sensor that measures the external temperature, and at least the measured skin temperature data and the external temperature data are associated with the elapsed measurement time. A body temperature measuring device including a storage unit for storing,
From the body temperature measuring device, the skin temperature data and the external temperature data associated with the stored measurement elapsed time are acquired, and at least, among the acquired skin temperature data, the temperature data until the predetermined time is reached is deleted. Then, for the skin temperature data and the external temperature data for each time other than the erased temperature data, the body temperature is calculated from the skin temperature data and the external temperature data and the coefficient value obtained from the body temperature measuring device and the thermal conductivity of the skin. It performs a specific calculation, and is related to the amount of change using the measured external temperature data from the relationship between the above-mentioned body temperature measuring device and the coefficient value obtained by the thermal conductivity of the skin with respect to the amount of change using the external temperature. A body temperature including a processing unit provided with a program for specifying and changing a numerical value, correcting the skin temperature using the changed coefficient value, hourly skin temperature data, and external temperature data to obtain the body temperature. Measurement processing device and
A body temperature measurement processing system characterized by having. A body temperature measurement processing system that measures the skin temperature and external temperature of the body and specifies the body temperature based on at least the elapsed time and the measured temperature data.
A skin temperature sensor that is worn on the body and measures the skin temperature, an external temperature sensor that measures the external temperature, and at least the measured skin temperature data and the external temperature data are associated with the elapsed measurement time. A body temperature measuring device including a storage unit for storing,
From the body temperature measuring device, the skin temperature data and the external temperature data associated with the stored measurement elapsed time are acquired, and at least, among the acquired skin temperature data, the temperature data until the predetermined time is reached is deleted. Then, with respect to the skin temperature data and the external temperature data for each time other than the erased temperature data, it is determined whether or not the amount of change using at least the measured external temperature data is equal to or more than a predetermined judgment value, and the change is made. If the amount is less than the above judgment value, the skin temperature is corrected to obtain the body temperature using the skin temperature data and the external temperature data and the coefficient value obtained from the thermal conductivity of the device and the skin, and the amount of change is the above judgment. If it is equal to or more than the above value, a body temperature measuring processing apparatus including a processing unit including a program for setting the latest skin temperature, which is set to the body temperature below the above-mentioned determination value, as the body temperature, and a body temperature measuring processing device including.
A body temperature measurement processing system characterized by having.

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