JP2003262687A - Data controller for organism consumption heat - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To properly control measuring time by an organism consumption heat measuring machine 5 of a simple constitution, and without bothering the user. <P>SOLUTION: Organism consumption heat, at each certain time interval set in advance, is measured and is recorded by providing the organism consumption heat measuring machine 5 with a clocking means 7 measuring elapsed time. When it is sent to a server 4 which controls the organism consumption heat data, an organic consumption heat measuring time operation means 13 calculates the measured time of the organism consumption heat data from the relation between the output of the clocking means 7 at transmission operation and the certain time interval set, in advance and the time of transmission operation, by a clocking means 12 provided in the server, and stores in the second organism consumption heat data together with the measured data. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a living body calorie consumption data management apparatus for managing measurement data of a living body heat consumption measuring device by a server.

[0002]

2. Description of the Related Art As a conventional living body heat consumption data management device of this type, there are devices described in, for example, JP 2001-218743 A and JP 10-295651 A. FIG. 9 shows a schematic configuration of a conventional living body heat consumption data management device described in the above publication.

In FIG. 9, a living body calorimeter 5 having a communication means 1, a clock function 2 and a memory 3 and having a mechanism for transmitting measurement data together with measurement time to a server 4 via the communication means 1, and Accumulate received data,
The server 4 is configured to judge a health condition based on the accumulated data, and transmit the measurement data and information related to the health condition in response to a request from the communication terminal 1.

[0004]

However, in the above-mentioned conventional configuration, since the living body calorie measuring instrument 5 has a clock function, the data of the measurement time will be incorrect unless the time of the clock is properly adjusted in advance. There is. In addition, it is a very troublesome action for the user to set a clock that does not have to know the time from the device, such as the living body calorimeter 5, and therefore an incorrect time is set. However, there is a problem that the risk of being made more serious and the authenticity of the data is impaired.

The present invention solves the above-mentioned conventional problems, and has a simple structure and is capable of appropriately managing the measurement time of the heat consumption data of a living body without bothering the user. The purpose is to provide.

[0006]

In order to solve the above-mentioned problems, the present invention provides a living-body calorie measuring instrument with a time-measuring means for measuring the elapsed time, and measures the living-body heat consumption at a preset constant time. Stored in memory, and when transmitting it to a server that manages living body heat consumption data, the relationship between the output of the time measuring means during the transmitting operation and the preset fixed time and the clock means provided in the server A living body heat consumption measurement time calculation means for calculating the measurement time of the living heat consumption data from the time of the transmission operation is provided.

Thus, the time difference between the time of the transmission operation and the time of the measurement of the heat consumption data of the living body can be known from the relationship between the time measurement of the preset constant time and the time measurement of the transmission operation in the living body heat consumption measuring device, and further transmission Since the time of operation is known by the clock means of the server, the measurement time of the living body heat consumption data can be calculated by subtracting the above time difference from the time of transmission operation.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The invention according to claim 1 is a time measuring means for measuring an elapsed time, and a heat consuming quantity for living body for repeatedly measuring a heat consuming quantity of a living body for every predetermined time set in advance based on an output of the time measuring means. Measuring means, first living heat consumption data storage means for sequentially storing living heat consumption data measured by the living heat consumption measuring means at regular time intervals,
A living body calorie measuring instrument comprising a sending data managing means for managing data to be transmitted to the outside, a clock means for measuring time, a transmission data from the living body calorie measuring instrument and an output of the clock means at the time of receiving the sending data. Based on the living body heat consumption measurement time calculating means for calculating the measurement time of the living body heat consumption data included in this transmission data, the living body heat consumption data transmitted from the living body heat consumption measuring device by the living body heat consumption measurement time calculating means A server, which comprises a second living body heat consumption data storage means for storing together with the calculated measurement time, and a communication means for communicating the transmission data between the living body heat consumption measuring device and the server via a communication network. By configuring from, the measurement of the preset constant time and the time of the transmission operation in the biological calorimeter The person in charge knows the time difference between the time of the transmission operation and the time when the living body heat consumption data was measured, and the time at the time of the transmission operation is known by the clock means of the server, so by subtracting the above time difference from the time of the transmission operation Calculate the measurement time of the calorific value data. In this way, with a simple configuration in which the biological heat consumption measuring device is not provided with the clock means and the time measuring means is provided, the measurement time of the measured data can be obtained without the need to adjust the clock of the biological heat consumption measuring device. Can be managed more easily and more accurately.

According to a second aspect of the present invention, there is provided a timer means for measuring elapsed time, a means for measuring heat consumption of a living body for repeatedly measuring a heat consumption amount of a living body at a predetermined time set in advance based on an output of the time keeping means, A living body heat consumption measuring device comprising a first living body heat consumption data storage means for sequentially storing living body heat consumption data measured by the living body heat consumption measuring means at regular intervals, and a transmission data management means for managing data to be transmitted to the outside. A communication means having a clock means for communicating the transmission data from the living body calorific value measuring instrument together with the time of the transmission operation via a communication network; and the transmitting data from the living body calorific value measuring instrument and the communication means. At the time of measuring the amount of heat consumed by the living body, which calculates the measurement time of the amount of heat consumed by the living body contained in this transmission data from the time at the time of transmission based on the output of the provided clock means Computation means, a server comprising a second living heat consumption data storage means for storing the living heat consumption transmitted from the living heat consumption measurement device together with the measurement time calculated by the living heat consumption measurement time calculation means By doing so, the relationship between the time of a certain time set in advance and the time of the transmission operation in the bio-heat consumption calorimeter can be understood from the time difference between the time of the transmission operation and that of the bio-heat consumption data measured. Since the time can be known by the clock means of the communication means, the measurement time of the living body heat consumption data is calculated by subtracting the above time difference from the time of the transmission operation. The same effect as the invention according to claim 1 can be obtained.

According to a third aspect of the present invention, the transmission data management means includes the plurality of living body heat consumption data measured at every fixed time stored in the first living body heat consumption data storage means together with the predetermined time. The latest living body heat consumption data that has not been expired and the corresponding measurement time are transmitted, so that the latest living body heat consumption data measured by the timekeeping means from the time of the transmission operation by the clock means of the server By tracing back the measurement time of, the time of the final living body calorie consumption data stored at regular time intervals can be known, and from that time, the measurement times previously stored can be sequentially calculated. In this case, the data to be stored in the first living body heat consumption data storage means is only the living body heat consumption data for every fixed time, and the storage capacity can be small.

According to a fourth aspect of the present invention, the transmission data management means transmits to the server all the living body heat consumption data stored in the first living body heat consumption data storage means. It is assumed that the time and the number of times to do are irregular by the user, and the data including the data already stored in the second living body heat consumption data storage means of the server is also transmitted. In this case, the processing on the transmitting side, that is, the heat consumption measuring device for living body is simplified, and it is easy to retain the memory for transmitting again when the data cannot be transmitted to the server successfully. There is.

According to a fifth aspect of the present invention, the transmission data management means is an untransmitted data for identifying the living body heat consumption data stored in the first living body heat consumption data storage means that has not been transmitted to the server. By including only the untransmitted data based on the untransmitted data identifying means when the data is transmitted, the data to be transmitted and the already stored heat consumption data storage means are stored in the second living body consumed heat amount data storing means. Since it avoids duplication with other data, there is an effect that the time required for transmission can be minimized and the amount of data processing on the server is reduced.

According to a sixth aspect of the present invention, the second living body heat consumption data storage means uses the living body heat consumption measurement time calculating means to store the living body heat consumption data transmitted from the living body heat consumption measuring device at regular time intervals. In the second living heat consumption amount data storage means of the server, the living body heat consumption data matching means for matching the data to be stored at the preset time interval is provided based on the calculated measurement time. , When the format is decided to store the data at time intervals based on the actual time, it was measured at a constant time interval with a living body calorimeter that has only a time measuring means for measuring only the elapsed time. Since the data is processed into a predetermined format and matched, it is convenient for managing a large number of users on the server, and it is easy to perform processing such as graphing after that. There is an advantage to say.

According to a seventh aspect of the present invention, the living body heat consumption data matching means calculates the value of the living body heat consumption data for every fixed time transmitted from the living body heat consumption measuring device by the living body heat consumption measurement time calculating means. Based on the measured time, the time is calculated for the data stored in the first living heat consumption data storage means by directly allocating to the closest time interval preset in the second living heat consumption data storage means. Since the deviation between the fixed time interval based on the means and the interval corresponding to the actual time stored in the second living heat consumption data storage means is distributed so as to be minimized while maintaining the value of the measured actual data. , The load of data processing on the server can be reduced.

In the eighth aspect of the present invention, the living body heat consumption data matching means calculates the value of the living body heat consumption data transmitted from the living body heat consumption measuring device at regular time intervals by the living body heat consumption measurement time calculating means. The data stored in the first living body calorie consumption data storage means is configured to be proportionally divided according to the time interval preset in the second living body heat consumption data storage means based on the measured time. When the data within a certain time period based on the time measuring means of the second living body heat consumption data storage means crosses the break corresponding to the actual time, the value of the data of the first living heat consumption data storage means is divided. Since it is apportioned according to the time distribution on both sides, it is possible to estimate a more accurate value that matches the real time.

According to a ninth aspect of the present invention, the living body calorie consumption measuring means calculates the living body heat consumption based on at least one of the number of steps, acceleration associated with movement, respiration rate, breath component, and heart rate. By doing so, it is possible to estimate the living body heat consumption with a simple configuration, and do not burden the body wearing and moving the living body heat consumption measuring device.

The invention according to a tenth aspect is the first to ninth aspects.
By using a program for causing a computer to execute at least a part of the heat consumption data management apparatus for living body according to any one of the above, it can be easily realized by a personal computer or the like, and by using a recording medium in which the program is recorded, Installation of the software at each user's home becomes easy.

[0018]

Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1) FIG. 1 is a diagram showing the configuration of Embodiment 1 of the present invention.

A pedometer 5 as a living calorie measuring device,
In the pedometer 5, the outputs of the step count counting unit 6, which counts the number of steps by a switch configured to open and close contacts according to the vibration caused by walking, the time counting unit 7, and the step counting unit 6 are set at regular intervals. A first step count data storage means 8 as a first living body calorie consumption data storage means to be stored;
A transmission data management unit 9 that manages transmission data to the communication unit 1 connected to the pedometer 5 based on the stored content of the first step count data storage unit 8 and the output of the timing unit 7, and the server 4.
A second step count data storage means 11 in which step count data transmitted from the pedometer 5 via the communication means 1 and the public line network 10 is stored in the server 4, and a clock means 12.
A step count measuring time calculator 13 is provided for calculating the time measured by the pedometer 5 based on the output of the clock 12 and the transmission data from the pedometer 5.

Further, the step count data temporary storage section 14 for temporarily storing the data from the step count counting section 6 in which the fixed time has not expired in the first step count data storage means 8
And a fixed time data storage unit 15 for transferring the data of which the fixed time has expired from the step count data temporary storage unit 14 and sequentially storing the data, and a fixed time data from the step count data temporary storage unit 14 based on the output of the time counting means 7. A data storage timing control unit 16 that controls the timing of transferring data to the storage unit 15 is provided.

Further, the second step count data storage means 11
Is provided with step count data matching means 17 for matching the step count data transmitted from the pedometer 5 with the actual time and storing the same.

Since the connection between the communication means 1 and the server 4 is realized by using a generally adopted means for performing data communication, the detailed configuration will be omitted.

Further, the pedometer 5 is provided separately from the communication means 1 during normal use, and the communication means 1 is provided only when transmitting data.
It is configured to connect to.

FIG. 2 is a diagram showing the stored contents of the first biometric information storage means 8. The stored data is the step count data for every fixed time, but in the present embodiment, the fixed time is 30 minutes, and 96 pieces of the step count data for two days are stored. In addition, data No. 0 is the step count data which is being counted by the step count counting section 6 and is used as the step count data temporary storage section 14. When 30 minutes expire, data No. The step count data of 0 is No. The oldest N is transferred to 1 and all data is moved up one by one accordingly.
o. The 95 data are deleted at that time. Note that N
o. 1 to No. The data of 95 is the content of the data storage unit 15 at regular time intervals.

FIG. 3 is a diagram showing the contents of the second step count data storage means 11. The stored data is for each of a plurality of users 18, users 19, and users 20, and the age, sex, and data of the users are the date and time of the step count data, the step count data, and the heat consumption calculated from the data. is there.

The operation of the above configuration will be described with reference to the flowchart of FIG.

Step 401 is a loop for monitoring whether the pedometer 5 is connected to the communication means 1 for data transmission. When the user wears the pedometer 5 to measure the number of steps, in step 402, the number of steps is accumulated from the step number counting unit 6 to the step number data temporary storage unit 14. In step 403, the data storage timing control unit 16 determines based on the time counting means 7 whether or not a fixed time set to 30 minutes has elapsed. When 30 minutes have elapsed, first, in step 404, the data storage unit 15 at fixed time intervals. The step count data of are sequentially replaced. Specifically, No. The data of No. 94 is No. 95, No. The data of No. 93 is No. No. 94, and so on. The data of No. 1 is No. Repeat until you move to 2. By this operation, the No. The oldest data in 95 is deleted. Thereafter, in step 405, the step count data of the step count data temporary storage unit 14, that is, No. The data of No. 0 is No. Then, the step count data temporary storage unit 14 is reset to 0 in step 406.

The operation up to this point is a normal operation when the user wears the pedometer 5.

It is confirmed in step 401 that the user has connected the communication means 1 and the pedometer 5 to send data to the server.
Then, the communication means 1 changes the pedometer 5 to the public network 1.
After connecting to the server 4 via 0, the transmission data managing means 9 determines the first step count data storing means 8 in step 407.
Of all the data, that is, the step count data in the step count data temporary storage unit 14 and the constant time data storage unit 15, and the fractional time that has not been completed for 30 minutes at the time of transmission, that is, the time corresponding to the step count stored in the step count data temporary storage unit 14. And are transmitted to the server 4. At step 408, the server 4 receives the data, and based on the output of the clock means 12 and the fractional time transmitted from the pedometer 5 at that time, the step count measurement time calculation means 13 transmits the measured step count time. Is calculated. In the method of calculating the measurement time in the step count measurement time calculation means 13, the fractional time that has not been completed in 30 minutes and the latest time when the pedometer 5 has completed the measurement time of 30 minutes are known from the time when the clock means 12 transmitted. The time can be specified for all the step count data every 30 minutes before that.

Further, in step 409, the step count data matching means 1 is used as the step count data as hourly data.
After allocating to the nearest real time using step 7, step 4
At step 10, it is stored in the second step count data storage means 11, and data as shown in FIG. 3 is created.

More specifically, referring to FIG. 5, assuming that the fractional time transmitted from the pedometer 5 is 20 minutes and the time is 18:30, the latest breaks every 30 minutes will be displayed. The time is 18:10. Therefore, before that, every 17 minutes at 17:40 and 17:10.
Minutes, and so on. Data is stored in the server 4 at hourly intervals of every hour, but the actual data values measured every 30 hours are not processed, but they are allocated to the closer ones at 17:00. The step count data from 10:17 to 17:40 and from 17:40 to 18:10 are added together and managed as data from 18:00 to 19:00 on the server. Latest fractional hours 2
The data from 18:10 to 18:30 corresponding to 0 minutes is set from 18:00 to 19:00. For this fractional time portion, if the number of steps is continuously counted after that and the step number data has reached 30 minutes, it will be updated again when the data is transmitted next time.

As described above, in the present embodiment, the pedometer 5 does not have a clock function, but is provided with a time measuring means capable of measuring only the elapsed time, and the pedometer data stored at every fixed time of 30 minutes is transmitted to the server 4. In doing so, the fractional time during which 30 minutes in the middle of the measurement is not completed is obtained from the output of the time measuring means 7 during the transmission operation and the division of the storage timing every 30 minutes, and this fractional time is provided in the server 4. The step count measurement time calculation means 13 calculates the measurement time of all the step count data from the time of the transmission operation by the clock means 12.

As a result, the time difference between the time of the transmission operation and the time of the measurement of the heat consumption data of the living body can be known from the relationship between the preset time of the heat consumption measuring instrument and the time of the transmission operation, and the further transmission Since the time of operation is known by the clock means of the server, the measurement time of the living body heat consumption data can be calculated by subtracting the above time difference from the time of transmission operation.

As described above, in the present embodiment, it is possible to accurately know the step count measurement time with a simple configuration. For the user, since the pedometer 5 does not have a clock means, it is not necessary to set the time, which is very convenient. At the same time, since there is no need to set the clock, there is no inconvenience of setting the wrong time, and the reliability of the data is high.

Further, in the present embodiment, the step count data measured every 30 minutes over the last two days is transmitted regardless of the frequency of transmission by the user, and the advantage is that the pedometer 5 is used. In addition to simplifying the configuration of the above, since no operation is performed on the data of the pedometer 5 when transmitting, even if a communication failure occurs during the transmitting operation, the server 4 prompts the retransmitting as it is. As described above, it is easy to restore data, so that there is an effect that the system has a simple configuration and reliability is increased.

Further, it is general that the division of the measurement time of the pedometer 5 does not match the division of the real time managed by the server 4, but in the present embodiment, the value of the data was left as it was. According to the step count measurement time, the process is distributed to the closer time division managed by the server 4. This processing is particularly advantageous when all the data stored in the pedometer 5 as described above is transmitted to the server 4, and the data transmitted by the user is duplicated in general use, but the value of the data is Since it is not processed, it is easy to check whether the data has already been transmitted in the past on the server 4 side.

In this embodiment, the public line network 10 is used for connecting the server 4 and the communication means 1, but other communication networks such as the Internet may be used.

Although the communication means 1 and the pedometer 5 are separately provided, they may be integrated.

(Second Embodiment) Next, a second embodiment of the present invention will be described. The difference from the first embodiment is that, as shown in FIG. 6, the clock means 12 is provided in the communication means 1 and the untransmitted data identification means 18 is provided in the transmitted data management means 9. Furthermore, the processing method of the step count data matching means 17 is divided into the real time division managed by the second step count data storage means 11 and the measurement time of the step count data calculated every 30 minutes by the step count measurement time calculation means 13. The value of data is distributed according to the real time division.

The operation will be described with reference to the flowchart of FIG.

First, in step 701, the untransmitted data counter of the untransmitted data identifying means 18 is set to 0, and the step count measurement is started. This process is performed every time after the data is transmitted to the server 4.

The following steps 702 to 707 are the same as the operation of the first embodiment, but when one piece of data that has expired for 30 minutes is newly stored in step 708, the untransmitted data counter is incremented by 1 accordingly. Is added.

When it is determined in step 703 that the pedometer 5 is connected to the communication means 1, the transmission data management means 9
Among the data of the first step count data storage means 8, the step count data of the constant time data storage part 15 and the step count data temporary storage of the number corresponding to the number of the untransmitted data counters in the untransmitted data identification means 18. The step count data of the unit 14 and the fractional time of 30 minutes not completed at the time of transmission are transmitted to the server 4. At the same time, the server 4 acquires the time output of the clock means 12 provided in the communication means 1. It should be noted that the step count data transmitted from the data storage unit 15 at fixed time intervals is from the newest one to the number of untransmitted data counters, but if the value of the untransmitted data counter is 95 or more, all the data is transmitted. Become.

In the next step 710, the step count measurement time calculating means 13 of the server 4 obtains the measurement time of the step count data as in the first embodiment.

Next, at step 711, the value of the transmitted step count data is processed as shown in FIG. Example 1
Similarly to the above, the data is stored in the server 4 at hourly intervals of every hour, and the value of the step count data corresponding to the division of the measurement time obtained by the step measurement time calculation means 13 and Apportion according to the time difference. In the example of FIG. 8, the time division managed by the server 4 is 17:00 and 18:00 in the figure. 18 of these
Paying attention to 0:00, the data of pedometer 5 is 17:40.
30 minutes from 18 minutes to 18 minutes
The time spans 0:00 and the value is 2,563 steps. This is apportioned according to time with 18:00 as a boundary, and 17
It is assumed that 1409 steps are from 14:00 to 18:00 and 854 steps are from 18:00 to 18:10. Therefore, 1
The data from 8:00 to 19:00 is 2416 steps by adding 1564 steps and 854 steps. Also, 17:00
From 0 minutes to 17:40, there are 863 steps, which is 18
It is included between 0:00 and 19:00, so leave it as it is, and 96: 40: 17: 17
Since it is 0 steps, 32 from 17:00 to 17:10
Assuming 0 steps, after all, 18:00 to 19:00 is 1
Add 709 steps, 863 steps, and 320 steps to make 2892 steps.

If 2416 steps in the fractional time portion are counted and the step count data has reached 30 minutes, the same as in the first embodiment, the next time the data is transmitted, it will be renewed. Will be updated.

Finally, in step 712, these values are stored in the second step count data storage means 11, and the process returns to the beginning.

Also in this embodiment, the advantage of not having the clock means 12 in the pedometer 5 is that the same effect as in Embodiment 1 can be obtained, and the time of the clock means 12 of the communication means 1 on the user side can be obtained. As an advantage of using the output, there are cases where it is more convenient to manage the data at the local time, such as when the user is in a place with a time difference, and the effect of reducing the complexity of the management at the server 4 is obtained. is there. For example, communication means 1
Since devices such as mobile phones and personal computers generally used as clocks have a clock function, it is relatively inevitable for the user to adjust the clock time.
Inconvenience rarely occurs.

Further, in the present embodiment, it is necessary to strengthen error management at the time of transmission as compared with the first embodiment, but the data once transmitted to the server is prevented from being redundantly transmitted at the next transmission. Therefore, there is an effect that the data traffic and the processing time can be reduced, and it is psychologically advantageous for the user that the communication time is short.

Further, as described in the first embodiment, it is general that the measurement time division of the pedometer 5 does not match the real time division managed by the server 4, but in the present embodiment, the data Since the value is apportioned according to the time difference,
The error from the actual becomes small.

In the above embodiments, the number of steps is measured as an example of the amount of heat consumed by the living body. However, the number of steps, acceleration associated with movement, respiratory rate, expiratory component, and heart rate are also used. It correlates with the amount of ecological heat consumed and can be used in the present invention. Furthermore, by using a plurality of them, it becomes possible to realize a more accurate living body calorie consumption measurement.

Further, in the above embodiments, by making a computer execute all or part of the operation, it can be easily realized by a personal computer or the like, and by using a recording medium recording the program. Installation of the software at each user's home becomes easy.

[0054]

As described above, according to the present invention, there is no inconvenience of setting a wrong time with a simple structure in which the biological heat consumption measuring device is not provided with a clock means, and the measurement time can be set. In addition to being able to manage accurately, the reliability of the data is high, and it is not necessary for the user to set the clock of the calorimeter for living body consumption.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a living body heat consumption data management device according to a first embodiment of the present invention.

FIG. 2 is a diagram showing the stored contents of a first step count data storage means as the first living body heat consumption data storage means.

FIG. 3 is a diagram showing the stored contents of a second step count data storage means as the second living body heat consumption data storage means.

FIG. 4 is a flowchart of the operation of the first embodiment.

FIG. 5 is an operation explanatory diagram of the step count data matching means as the living body heat consumption data matching means.

FIG. 6 is a configuration diagram of a living body heat consumption data management device according to a second embodiment of the present invention.

FIG. 7 is a flowchart of the operation of the second embodiment.

FIG. 8 is an operation explanatory diagram of the step count data matching means as the living body heat consumption data matching means.

FIG. 9 is a block diagram of a conventional living body heat consumption data management device.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Communication means 4 Server 5 Pedometer as a living body calorie consumption measuring device 6 Step count part 7 as a living body heat consumption measuring means 7 Clocking means 8 First step number data storing means 9 as a first living body consumed heat amount data storing means 9 Transmission Data management means 11 Second step count data storage means 12 as second living body heat consumption data storage means 12 Clock means 13 Step count measurement time calculation means 17 as living body heat consumption measurement time calculation means 17 Step count as living body heat consumption data matching means Data matching means 18 Untransmitted data identifying means

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Masayo Yamamoto             1006 Kadoma, Kadoma-shi, Osaka Matsushita Electric             Sangyo Co., Ltd. F term (reference) 2F002 AA00 AA04 AA05 AD06 AD07                       BB00 BB04 DA00 GA04

Claims (10)

[Claims] 1. A time measuring means for measuring an elapsed time, a living body consumed heat amount measuring means for repeatedly measuring a living body consumed heat amount at a predetermined time set based on an output of the time keeping means, and a living body consumed heat amount measuring means for measuring. The living body calorie consumption data storage means for sequentially storing the living body heat consumption data for every fixed time, the living body heat consumption measuring machine including the transmission data management means for managing the data to be transmitted to the outside, and the clock means for measuring the time. , A living heat consumption measurement time calculating means for calculating the measurement time of the living heat consumption data included in the transmission data based on the output of the clock means at the time of receiving the transmission data and the transmission data from the living heat consumption measuring device, The measurement time calculated by the living heat consumption measurement time calculating means based on the living heat consumption data transmitted from the living heat consumption measuring device. And a communication means for communicating the transmission data via a communication network between the living body heat consumption measuring device and the server. Biomass consumption data management device. 2. A time measuring means for measuring an elapsed time, a living body calorie measuring means for repeatedly measuring a living body consumed heat quantity at a preset time based on an output of the time measuring means, and a living body consumed heat quantity measuring means for measuring. A first living body heat consumption data storage means for sequentially storing living body heat consumption data for each fixed time, a living body heat consumption measuring device comprising a transmission data management means for managing data to be transmitted to the outside, and a clock means, Communication means for communicating the time of the transmission operation together with the transmission data from the living body calorific value measuring device via a communication network, the transmission data from the living body calorie measuring device and the output of the clock means provided in the communication means Heat consumption measurement time calculation means for calculating the measurement time of the heat consumption data included in this transmission data from the time of transmission based on Living heat consumption data management including a server including a second living heat consumption data storage unit that stores the living heat consumption transmitted from a calorimeter together with the measurement time calculated by the living heat consumption measurement time calculation unit apparatus. 3. The transmission data management means, together with a plurality of living body heat consumption data measured at fixed time intervals stored in the first living body heat consumption data storage means, the latest living body whose fixed time has not expired. 3. The heat consumption data and the measurement time corresponding to the heat consumption data are transmitted.
The living body heat consumption data management device according to any one of items. 4. The living body heat consumption data management device according to claim 3, wherein the transmission data management means is configured to transmit all living body heat consumption data stored in the first living heat consumption data storage means. 5. The transmitted data management means has an untransmitted data identification means for identifying the living body heat consumption data stored in the first living body heat consumption data storage means that has not been transmitted to the server. 4. The living body calorie consumption data management device according to claim 3, wherein only untransmitted data is transmitted based on the untransmitted data identifying means during transmission. 6. The second living body heat consumption data storage means,
Based on the measurement time calculated by the heat consumption measuring device for heat consumption of living body, the heat consumption data of the living body for every fixed time transmitted from the heat consumption measuring machine of the living body is matched with the data to be stored at a preset time interval. The living body heat consumption data management device according to claim 1, wherein the living body heat consumption data matching means is provided. 7. The living body heat consumption data matching means calculates the value of the living body heat consumption data transmitted from the living body heat consumption measuring device at regular time intervals based on the measurement time calculated by the living body heat consumption measurement time calculation means. 7. The living body heat consumption data management device according to claim 6, wherein the second living body heat consumption data storage means is configured to distribute the living body heat consumption data directly to the closest time interval set in advance. 8. The heat consumption data matching means for living body calculates the value of the heat consumption data for living body transmitted from the heat consumption measuring device for living body at regular intervals based on the measurement time calculated by the means for calculating heat consumption of living body measurement time calculating means. 7. The living body heat consumption data management device according to claim 6, wherein the second living body heat consumption data storage means is configured to apportion in accordance with a preset time interval delimiter. 9. The living body heat consumption measuring means is configured to calculate the living body heat consumption based on at least one of the number of steps, acceleration accompanying movement, respiration rate, breath component, and heart rate. The living body heat consumption data management device according to any one of items. 10. A program for causing a computer to execute at least a part of the living body heat consumption data management device according to claim 1.