JP2003242477A - Pedometer, and health care system based on data of the number of steps - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pedometer, capable of accurately detecting the number of steps no matter how is placed in a pocket of clothes or a carrying bag without fixing the pedometer to a waist belt, and to obtain health care data by automatically taking the data of the number of steps in an information terminal. <P>SOLUTION: This pedometer 1 is formed by a three-axis acceleration sensor 2 for detecting the acceleration in X, Y and Z directions, CPU 3 for processing the detected acceleration data to detect the number of steps, a display part 4 for displaying the number of steps, a power supply part 5 for driving the pedometer 1, and an information terminal interface 6 capable of communicating with the outside. The pedometer 1 is inserted in a designated interface 8 of the information terminal 7 for the pedometer to take the data of the number of steps in the information terminal 7, and the data of the number of steps is processed in the information terminal to obtain health care data. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a pedometer used for walking, and a pedometer used for walking, in recent years, when the heat of walking is increasing as a health promoting means or a health maintaining means in a world rapidly aging. It relates to a data-based health management system.

[0002]

2. Description of the Related Art Pedometers for measuring the number of steps and performing simple analysis such as calculation of calorie consumption from the measured data have been available. This pedometer will be described with reference to the block diagram of FIG. 7. The pedometer is a sensor 21 for detecting a vibration of walking, a step number detecting means 23 for detecting the number of steps by receiving an output from the sensor 21, and a detected value. Operation unit 2
5, a display unit 27 for displaying the number of steps and the like, an input unit 29 for switching the display, the step number detecting means 23, the arithmetic unit 2
5. A primary battery 31 that supplies electric power to the display unit 27.

Then, the vibration generated by the motion of one foot kicking the ground and the other foot landing on the ground, which is accompanied by the movement of the leg during walking, is detected, and is detected at this time. The number of vibrations is measured as the number of steps during walking, and the calorie consumption is calculated according to a predetermined formula based on the number of steps.

As described above, the step count can be counted, the step count data for several days can be managed, and the health check data such as calorie consumption can be calculated and displayed to some extent based on the step count data. The total is coming out.

However, regarding the conventional pedometer,
Since a pendulum with a magnet and a sensor that uses a reed switch are used for the mechanism of the pedometer, the pedometer cannot be detected unless it is placed in the specified direction, and the power supply of the pedometer cannot be detected. Since the primary battery was used, it was necessary to replace the battery.

Furthermore, it is not possible to store long-term past step count data in the pedometer main body and to transfer the step count data from the pedometer to an external device.
Therefore, various data obtained by the pedometer need to be stored and managed by a person who thinks about health by inputting them into a personal computer. It was not possible to do so, and a lot of data had to be entered into the information terminal (personal computer, etc.) to manage it, which made the task troublesome.

Therefore, the present invention provides a pedometer which can detect the pedometer in any direction, such as in a pocket of clothes or a handbag, without fixing the pedometer to a waist belt or the like, Furthermore, the pedometer is connected to an information terminal (personal computer, PDA, terminal installed in a station or a convenience store, etc.) by a simple means, and the power unit of the pedometer is charged from the power unit of the information terminal. The purpose is to automatically take the total step count data into the information terminal, and to create and display the health management data based on the step count data in the information terminal to perform the health management.

[0008]

Means for Solving the Problems The means of the present invention for solving the above-mentioned problems include a triaxial acceleration sensor for detecting accelerations in X, Y and Z directions, and acceleration data detected by the triaxial acceleration sensor. CP that processes the number of steps to detect the number of steps
The pedometer has a configuration including U, a pedometer displaying the pedometer, a power source driving the pedometer, and an information terminal interface capable of communicating with the outside.

Then, a triaxial acceleration sensor for detecting accelerations in the X, Y and Z directions, and C for processing the acceleration data detected by the triaxial acceleration sensor to detect the number of steps.
A pedometer including a PU, a pedometer display unit that displays the pedometer count, a power supply unit that drives a pedometer, and an interface for an information terminal, the pedometer interface, a pedometer data processing unit, and the pedometer data processing unit. Health management based on step count data configured by a display unit for displaying health management data obtained by the means, a storage unit for storing the health management data, and an information terminal including a power supply unit for driving the information terminal. In the system.

The acceleration data detected by the three-axis acceleration sensor is a pedometer having a motion form determining means for determining whether the acceleration data is obtained by walking or running or other than that, and the pedometer. It is in a health management system based on step count data.

The pedometer is connected to the information terminal to charge the power supply of the pedometer from the power supply of the information terminal, and a health management system based on the pedometer data. .

Further, the present invention is a pedometer that uses a secondary battery as a power source of the pedometer, and a health management system based on the pedometer data.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION Next, embodiments of a pedometer and a health management system based on the pedometer data according to the present invention will be described with reference to the drawings.

FIG. 1 is a schematic configuration diagram of a pedometer 1 according to the present invention, which is a triaxial acceleration sensor 2 for detecting accelerations in X, Y, and Z directions, and an X, X detected by the triaxial acceleration sensor 2. It is composed of a CPU 3 that processes acceleration data in the Y and Z directions to detect the number of steps, a step number display unit 4 that displays the number of steps, a power source unit 5 that drives the pedometer 1, and an information terminal interface 6. The pedometer 1 is shown.

FIG. 2 is a step count detection state diagram by the pedometer 1 of the present invention, showing how the step count can be detected even if the pedometer 1 is placed in any orientation. The pedometer 1 is a triaxial acceleration sensor 2 that can detect acceleration in the triaxial directions of X, Y, and Z with one sensor chip.
Therefore, it is possible to detect the number of steps even if the pedometer 1 is placed in any direction.

Further, the acceleration intensity ratio can be calculated by the triaxial acceleration sensor 2, and walking on level ground, running on level ground, climbing stairs,
Body vibration caused by movement such as stairs descending, bus, car,
It is also possible to identify whether the body vibration is due to external vibration when getting on a train or the like, and it is possible to more accurately calculate the number of steps.

Therefore, without fixing the pedometer 1 to a waist belt or the like as in the conventional case, it is possible to accurately detect the number of steps even if the pedometer 1 is placed in any direction such as a pocket of clothes or a handheld bag. .

FIG. 3 shows a triaxial acceleration sensor 2 for detecting accelerations in the X, Y, and Z directions, and acceleration data in the X, Y, and Z directions detected by the triaxial acceleration sensor 2 to process the number of steps. Pedometer 1 including a CPU 3 for detection, a pedometer display unit 4 for displaying the pedometer count, a power supply unit 5 for driving the pedometer 1, and an information terminal interface 6 capable of communicating with the outside, and a pedometer interface 8 A step count data processing unit 9, a display unit 10 for displaying health management data created by the step count data processing unit, a storage unit 11 for storing the health management data, and a power supply unit 12 for driving the information terminal 7. FIG. 3 is a schematic configuration diagram of a health management system based on step count data when the information terminal 7 including and is connected by a simple means.

For example, by inserting the pedometer 1 into a predetermined pedometer interface 8 of the information terminal 7, the power supply unit 5 of the pedometer 1 is charged from the power supply unit 12 of the information terminal 7 while the pedometer is being charged. The step count data of 1 can be automatically taken into the information terminal 7.

Further, by using a secondary battery such as a lithium battery for the power supply unit 5 of the pedometer 1 instead of the conventional primary battery, it becomes possible to save the labor of battery replacement.

FIG. 4 is another schematic configuration diagram of the health management system based on the step count data, which is the storage unit 11 of the information terminal 7.
2 shows a mechanism for transferring the health management data stored in the above from the mobile phone terminal interface 13 provided in the information terminal 7 to the server 15 via the mobile phone terminal 14.

Therefore, by transferring the health management data created by the information terminal 7 to the server 15 using the portable telephone terminal 14 based on the step count data detected by the pedometer 1, the server 15 You will be able to save and manage even in.

The data transfer system for transferring the health management data from the information terminal 7 to the server 15 is usually the mobile phone terminal 14, but if the data transfer distance is short, wireless communication such as Bluetooth system is also conceivable.

FIG. 5 is a flow chart showing the procedure of the health management system based on the step count data of the pedometer 1 of the present invention.

First, the pedometer 1 of the present invention is attached to a part of the body or put in a pocket of clothes, a bag or the like held by a person to start walking, and the step count data up to a desired position is acquired. .

Next, the pedometer 1 is inserted into a predetermined pedometer interface 8 of the information terminal 7 to take the step count data into the information terminal 7.

Furthermore, the step count data fetched by the information terminal 7 is automatically processed by the step count data processing unit 9 of the information terminal 7 to create health care data, which is displayed on the display unit 10 of the information terminal 7. To be done.

The display example of the health management data is as shown in FIGS. 6 (a), 6 (b) and 6 (c), and it is possible to display the step count data in the past several months in the form of a graph or internationally. Obesity used BMI (Body Mass Ind)
ex): Weight (kg) / height (m) ² is calculated, and 22 can perform standard health management, calorie consumption from step count data, and the like.

Further, the parties confirm the health management data, and if necessary, the health management data stored in the storage unit 11 of the information terminal 7 is transferred from the mobile phone terminal interface 13 of the information terminal 7 to the mobile phone terminal 14. It can also be transferred to the server 15 via the server for storage management.

[0030]

Therefore, according to the pedometer of the present invention and the health management system based on the pedometer data, it is possible to detect the pedometer even if the pedometer is placed in any direction, which is not seen in the conventional pedometer. , "You can save the trouble of replacing the battery of the pedometer", "You can automatically transfer the step count data of the pedometer to the information terminal, and immediately calculate the health management data on the information terminal." It is possible to display a special effect such as "can be displayed".

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of a pedometer according to the present invention.

FIG. 2 is a step count detection state diagram by the pedometer of the present invention.

FIG. 3 is a schematic configuration diagram of a health management system based on step count data of the present invention.

FIG. 4 is another schematic configuration diagram of a health management system based on step count data of the present invention.

FIG. 5 is a flowchart showing a procedure of the health management system based on the step count data of the pedometer of the present invention.

FIG. 6 is a display example of health management data displayed on the display unit of the information terminal in the health management system based on the step count data of the present invention.

FIG. 7 is a block diagram showing a configuration of a conventional pedometer.

[Explanation of symbols]

1 pedometer 2 Triaxial acceleration sensor 3 CPU 4 Step count display 5 power supply 6 Information terminal interface 7 Information terminal 8 Pedometer interface 9 Step data processing unit 10 Health management data display 11 Memory 12 power supply 13 Mobile phone terminal interface 14 Mobile phone terminals 15 servers

Claims (5)

[Claims] 1. A triaxial acceleration sensor for detecting accelerations in X, Y, and Z directions, and a CPU for processing acceleration data detected by the triaxial acceleration sensor to detect a step count.
And a step count display section for displaying the step count, a power supply section for driving the pedometer, and an information terminal interface. 2. A triaxial acceleration sensor that detects accelerations in X, Y, and Z directions, and a CPU that processes acceleration data detected by the triaxial acceleration sensor to detect a step count.
A pedometer including a pedometer display unit that displays the pedometer count, a power supply unit that drives the pedometer, an information terminal interface, a pedometer interface, and a pedometer data processing unit,
And a display unit for displaying the health management data obtained by the step count data processing unit, a storage unit for storing the health management data, and an information terminal including a power supply unit for driving the information terminal. A health management system based on characteristic step count data. 3. A motion form discriminating means for discriminating whether the acceleration data detected by the triaxial acceleration sensor is obtained by walking or running, or by other than that. A pedometer according to claim 1 or 2, and a health management system based on the pedometer data. 4. The power supply unit of the pedometer is charged from the power supply unit of the information terminal by connecting the pedometer and the information terminal. Pedometer and health management system based on the pedometer data. 5. The pedometer according to claim 1, 2, 3 or 4, wherein a power source of the pedometer uses a secondary battery, and a health management system based on the pedometer data.