JP2017083445A - Information measurement device, and information measurement system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To accurately measure the information about an operation of a measurement object without being affected by an inertial force.SOLUTION: An attitude detection unit 100 includes: an inclination sensor 110 for detecting inclination information of an own device; and a measurement control unit 131 for measuring the operation information about an operation of a measurement object on the basis of the inclination information detected by the inclination sensor 110. The inclination sensor 110 includes: a pressure sensor that is disposed relatively movably with respect to the own device and detects the pressure of fluid; and an inclination information detection unit for detecting the inclination information on the basis of the output of the pressure sensor and the movement information of the pressure sensor.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an information measuring device and an information measuring system.

  2. Description of the Related Art In recent years, a technique for measuring information about a user's movement such as the posture, movement, and movement of a user wearing the information measurement apparatus using an information measurement apparatus such as a wearable terminal has been known (for example, Patent Documents). 1 and Patent Document 2). For example, in the technique described in Patent Document 1, a body shake before starting exercise is detected using an acceleration sensor. In the technique described in Patent Document 2, the motion of the head is detected using a gyro sensor.

JP 2009-233092 A JP-T-2001-520903

However, since the technique described in Patent Document 1 uses an acceleration sensor, for example, it is difficult to measure information related to the movement of a measurement subject such as posture and movement during exercise without being affected by inertial force. Met. In the technique described in Patent Document 2, angular acceleration detected by the gyro sensor is used. For this reason, in the technique described in Patent Document 2, in order to detect information related to the movement of the measurement subject, an integration process for calculating an angle from the angular velocity is required. Therefore, errors may be accumulated and detection accuracy may be reduced. is there.
Thus, with the conventional technology, it has been difficult to accurately measure information relating to the movement of the measurement subject without being affected by the inertial force.

  The present invention has been made to solve the above problems, and an object of the present invention is to provide an information measuring apparatus and an information measuring system capable of accurately measuring information related to the movement of a measurement subject without being influenced by inertial force. It is to provide.

  In order to solve the above-described problem, according to one aspect of the present invention, an inclination sensor that detects inclination information of the device itself, and operation information related to an operation of a measurement target person is measured based on the inclination information detected by the inclination sensor. The inclination sensor is disposed so as to be relatively movable with respect to the apparatus, a pressure sensor for detecting the pressure of the fluid, an output of the pressure sensor, and movement information of the pressure sensor; And an inclination information detecting unit for detecting the inclination information based on the information measuring device.

  Further, according to one aspect of the present invention, in the information measurement apparatus, the inclination sensor includes a movement mechanism that moves the pressure sensor along a predetermined movement path with respect to the apparatus, and the inclination information detection unit includes: The inclination information is detected based on movement information of the pressure sensor moved along the predetermined movement path by the movement mechanism and an output of the pressure sensor.

  Further, according to one aspect of the present invention, in the above information measurement device, the moving mechanism includes a rotating body on which the pressure sensor is arranged, and moves the pressure sensor in a circular shape by rotating the rotating body. The inclination information detection unit executes synchronous detection based on a periodic output signal that is moved from the predetermined movement path and is output from the pressure sensor, and a reference signal that is based on the movement information. The inclination information is detected based on the result of detection.

  In one embodiment of the present invention, in the information measurement device, the inclination information includes inclination information in a first direction and inclination information in a second direction orthogonal to the first direction. The inclination information detection unit performs synchronous detection based on the periodic output signal and a first reference signal based on the movement information, and based on a result of the synchronous detection, the first direction Is detected, and synchronous detection is performed based on the periodic output signal and the second reference signal whose phase is shifted by 90 degrees from the first reference signal, and the result of the synchronous detection is obtained. Based on this, the inclination information in the second direction is detected.

  Further, according to one aspect of the present invention, in the information measurement apparatus, the measurement control unit determines whether or not the tilt information detected by the tilt information detection unit is within a predetermined reference range. Based on the determination result, a notification regarding the operation information is output to the output unit.

  In addition, according to one aspect of the present invention, in the information measurement apparatus, the measurement control unit may check that the inclination information is the first threshold when the inclination information is equal to the first threshold. An alarm to be displayed is output to the output unit as a notification regarding the operation information.

  Further, according to one aspect of the present invention, in the information measurement apparatus, the measurement control unit has the inclination information equal to or greater than the second threshold when the inclination information is equal to or greater than a second threshold. An alarm indicating this is output to the output unit as a notification regarding the operation information.

  Further, according to one aspect of the present invention, in the information measurement apparatus, the measurement control unit may be configured such that the inclination information is equal to or lower than the third threshold when the inclination information is equal to or lower than a third threshold. An alarm indicating this is output to the output unit as a notification regarding the operation information.

  Further, according to one aspect of the present invention, in the information measurement apparatus, the measurement control unit may be configured such that the inclination information is out of the predetermined reference range when the inclination information is not within the predetermined reference range. An alarm indicating this is output to the output unit as a notification regarding the operation information.

  Further, according to one aspect of the present invention, in the information measurement apparatus, the measurement control unit may be configured such that the inclination information is within the predetermined reference range when the inclination information is within the predetermined reference range. A warning indicating that the output information is output to the output unit as a notification regarding the operation information.

  Further, according to one aspect of the present invention, in the information measurement apparatus, the measurement control unit includes an operation pattern indicating a change in the inclination information with respect to time, and a reference pattern serving as a reference for the predetermined operation pattern. A comparison is made, and a notification regarding the operation information is output to the output unit based on the comparison result.

  According to another aspect of the present invention, the information measuring apparatus includes a temperature sensor that detects a temperature, and a temperature correction unit that corrects the inclination information based on the temperature detected by the temperature sensor. Features.

  Further, according to one aspect of the present invention, in the above information measurement device, an absolute pressure sensor that detects atmospheric pressure, and an atmospheric pressure correction unit that corrects the inclination information based on the atmospheric pressure detected by the absolute pressure sensor. It is characterized by providing.

  In addition, according to an aspect of the present invention, in the information measurement apparatus, the motion information includes information indicating a posture or motion of a measurement target person wearing the device.

  According to another aspect of the present invention, there is provided an information measurement system including the information measurement apparatus that can be attached to a measurement target and a control device that controls the information measurement apparatus. It is.

  Further, one aspect of the present invention is the information measurement system described above, wherein the information measurement system includes a plurality of the information measurement devices, and each of the plurality of information measurement devices is attached to a different part of the measurement subject. And

  ADVANTAGE OF THE INVENTION According to this invention, the information regarding a measurement subject's operation | movement can be measured correctly, without being influenced by inertia force.

It is an external view which shows an example of the attitude | position detection unit by 1st Embodiment. It is a functional block diagram which shows an example of the attitude | position detection unit by 1st Embodiment. It is a figure which shows the example of data of the measurement data storage part in 1st Embodiment. It is a figure which shows the example of data of the reference value memory | storage part in 1st Embodiment. It is a block diagram which shows an example of the inclination sensor by 1st Embodiment. It is a figure explaining the usage example of the attitude | position detection unit by 1st Embodiment. It is a figure which shows an example of operation | movement of the synchronous detection part in 1st Embodiment. It is a figure which shows an example of operation | movement of the inclination sensor by 1st Embodiment. It is a flowchart which shows an example of operation | movement of the attitude | position detection unit in 1st Embodiment. It is a functional block diagram which shows an example of the attitude | position detection unit by 2nd Embodiment. It is a block diagram which shows an example of the inclination sensor by 2nd Embodiment. It is a figure which shows an example of operation | movement of the synchronous detection part by 2nd Embodiment. It is a figure which shows an example of operation | movement of the inclination sensor by 2nd Embodiment. It is a functional block diagram which shows an example of the attitude | position detection unit by 3rd Embodiment. It is a block diagram which shows an example of the inclination sensor by 3rd Embodiment. It is a functional block diagram which shows an example of the attitude | position detection system by 4th Embodiment. It is a figure which shows the example of data of the unit information storage part in 4th Embodiment. It is a figure which shows the example of data of the operation | movement pattern memory | storage part in 4th Embodiment. It is a flowchart which shows an example of operation | movement of the attitude | position detection system in 4th Embodiment. It is a block diagram which shows the inclination sensor of a 1st modification. It is a block diagram which shows the inclination sensor of a 2nd modification. It is a block diagram which shows the inclination sensor of a 3rd modification. It is a block diagram which shows the inclination sensor of a 4th modification.

Hereinafter, an information measuring device and an information measuring system according to an embodiment of the present invention will be described with reference to the drawings.
[First Embodiment]
FIG. 1 is an external view showing an example of a posture detection unit 100 according to the first embodiment.
As shown in FIG. 1, the posture detection unit 100 is, for example, a wearable terminal, and has a belt BT (support portion) that can be attached to a user's (measurement target) abdomen, arm, thigh, and the like. doing. The posture detection unit 100 includes an operation unit 111 and a display unit 112 as shown in FIG. In the present embodiment, an attitude detection unit 100 will be described as an example of an information measurement device. The posture detection unit 100 measures, for example, the posture of the user and the motion of the user as information related to the motion of the user.
In FIG. 1, an XYZ orthogonal coordinate system is set, and a direction orthogonal to the paper surface is defined as an X-axis direction, a horizontal direction of the paper surface is defined as a Y-axis direction, and a vertical direction of the paper surface is defined as a Z-axis direction. Here, the XY plane is a horizontal plane, and in the following description, description will be made based on the XYZ orthogonal coordinate system shown in FIG.

FIG. 2 is a functional block diagram illustrating an example of the posture detection unit 100 according to the present embodiment.
As shown in FIG. 2, the posture detection unit 100 includes a tilt sensor 110, an operation unit 111, a display unit 112, an output unit 113, a communication unit 114, a storage unit 120, and a control unit 130. Yes.

The inclination sensor 110 detects inclination information of the posture detection unit 100 (self apparatus). Here, the tilt information is, for example, the tilt angle θ of the posture detection unit 100. The details of the configuration of the tilt sensor 110 will be described later.
The operation unit 111 is an input device such as a switch or a touch panel as shown in FIG. The operation unit 111 receives various types of information through operations by the user.

The display unit 112 is a liquid crystal display, for example, and displays various information such as an operation screen of the posture detection unit 100 and a message display.
The output unit 113 notifies the user of various alarms (warnings). The output unit 113 is, for example, a speaker that outputs sound, a vibration motor that generates vibration, a light emitting diode that generates light, a headphone amplifier that outputs a sound signal for headphones, and the like.

The communication unit 114 is connected to another device (for example, another posture detection unit 100 or a portable terminal such as a smartphone) by wireless communication such as Bluetooth (registered trademark) or wireless LAN (Local Area Network). Communicate with.
The storage unit 120 stores various types of information used for processing executed by the posture detection unit 100. The storage unit 120 includes a measurement data storage unit 121 and a reference value storage unit 122.

The measurement data storage unit 121 stores inclination information (for example, an inclination angle θ) detected by the inclination sensor 110. The measurement data storage unit 121 stores, for example, measurement data in which the detected time information is associated with the inclination angle θ.
FIG. 3 is a diagram illustrating a data example of the measurement data storage unit 121 in the present embodiment.
As illustrated in FIG. 3, the measurement data storage unit 121 stores “time” and “inclination angle (θ)” in association with each other. Here, “time” indicates time information when the inclination angle θ is detected by the inclination sensor 110, and “inclination angle (θ)” indicates the inclination angle θ.
In the example illustrated in FIG. 3, the “tilt angle (θ)” detected at “t0” as “time” is “0” (degrees). Further, the “tilt angle (θ)” detected at “t1” at “time” is “5” (degrees).

  In the present embodiment, the tilt angle θ is an example of information indicating the posture of the user, and the measurement data storage unit 121 stores an operation pattern indicating a change of the tilt angle θ with respect to time. Here, the operation pattern is an example of information indicating a user's operation. The information indicating the user's posture and the information indicating the user's motion are examples of motion information related to the user's motion.

Returning to the description of FIG. 2, the reference value storage unit 122 stores various reference values indicating criteria for determining whether or not the posture detection unit 100 notifies an alarm. For example, as illustrated in FIG. 4, the reference value storage unit 122 stores a first threshold value, a second threshold value, a third threshold value, a reference range upper limit value, and a reference range lower limit value.
FIG. 4 is a diagram illustrating a data example of the reference value storage unit 122 in the present embodiment.
In this figure, the first threshold value, the second threshold value, and the third threshold value indicate whether the measurement control unit 131 of the control unit 130, which will be described later, notifies an alarm with respect to the tilt angle θ detected by the tilt sensor 110. This is threshold information for determining whether or not. Details of the first threshold, the second threshold, and the third threshold will be described later. The reference range upper limit value and the reference range lower limit value indicate a reference range for the measurement control unit 131 to determine whether or not to notify an alarm with respect to the inclination angle θ detected by the inclination sensor 110. The reference range upper limit value indicates the upper limit value of the reference range, and the reference range lower limit value indicates the lower limit value of the reference range.

Returning to the description of FIG. 2 again, the control unit 130 is, for example, a processor including a CPU (Central Processing Unit) and the like, and comprehensively controls the posture detection unit 100. For example, the control unit 130 includes a measurement control unit 131.
The measurement control unit 131 measures motion information (for example, information indicating posture and motion) related to the user's motion based on the tilt information (tilt angle θ) detected by the tilt sensor 110. The measurement control unit 131 periodically acquires the inclination angle θ detected by the inclination sensor 110, associates the acquired inclination angle θ with time information, and stores them in the measurement data storage unit 121 as shown in FIG. Remember.

  In addition, the measurement control unit 131 sets a condition that the tilt angle θ detected by the tilt sensor 110 is based on the reference value stored in the reference value storage unit 122 based on the tilt angle θ detected by the tilt sensor 110. It is determined whether or not the condition is satisfied, and the output unit 113 outputs an alarm according to the determination result. For example, the measurement control unit 131 determines whether or not the inclination angle θ detected by the inclination information detection unit 40 is within a predetermined reference range, and based on the determination result, the output unit 113 notifies the operation information. To output. Here, the predetermined reference range includes, for example, a range equal to or larger than a predetermined threshold, a range equal to or smaller than the predetermined threshold, a range between a predetermined upper limit value and a predetermined lower limit value, and a position equal to the predetermined threshold value. It is.

For example, when the tilt angle θ is equal to the first threshold value, the measurement control unit 131 generates an alarm (alarm) indicating that the tilt angle θ has reached the first threshold value stored in the reference value storage unit 122. The output unit 113 outputs the notification regarding the operation information. Here, the output unit 113 outputs, for example, a predetermined pattern of sound, light, vibration, or the like as the notification related to the operation information.
In addition, the measurement control unit 131, for example, when the inclination angle θ is equal to or larger than the second threshold stored in the reference value storage unit 122, an alarm indicating that the inclination angle θ is equal to or larger than the second threshold. (Alarm) is output to the output unit 113 as a notification regarding the operation information.

In addition, for example, when the inclination angle θ is equal to or smaller than the third threshold stored in the reference value storage unit 122, the measurement control unit 131 indicates an alarm indicating that the inclination angle θ is equal to or smaller than the third threshold. (Alarm) is output to the output unit 113 as a notification regarding the operation information.
In addition, for example, when the inclination angle θ is not within a predetermined reference range, the measurement control unit 131 outputs an alarm (alarm) indicating that the inclination angle θ is out of the predetermined reference range as a notification regarding operation information. Output to the unit 113. Here, the predetermined reference ranges are the reference range upper limit value and the reference range lower limit value stored in the reference value storage unit 122, and the measurement control unit 131 determines that the inclination angle θ is the reference range upper limit value and the reference range lower limit value. It is determined whether the value is between values. The measurement control unit 131 causes the output unit 113 to output an alarm when the inclination angle θ is not a value between the reference range upper limit value and the reference range lower limit value.

Next, the configuration of the tilt sensor 110 according to the present embodiment will be described with reference to FIG.
FIG. 5 is a block diagram illustrating an example of the tilt sensor 110 according to the present embodiment.
As shown in FIG. 5, the inclination sensor 110 includes a pressure sensor 10, a moving mechanism 20, a magnet 31, a rotation detection unit 32, a synchronous clock signal generation unit 33, a power supply unit 34, a slip ring 35, An inclination information detection unit 40 is provided.

  The pressure sensor 10 detects the pressure of a fluid such as air or liquid, for example. The pressure sensor 10 is disposed so as to be movable relative to the posture detection unit 100. For example, the pressure sensor 10 is arranged on the rotating plate 21 so as to be movable in a circular shape by a rotating motion of the rotating plate 21 of the moving mechanism 20 described later. The pressure sensor 10 includes, for example, a differential pressure sensor (relative sensor) whose resistance value changes due to physical deformation due to pressure, a Wheatstone bridge circuit having the differential pressure sensor as a part of resistance, and an output amplifier. The pressure (for example, atmospheric pressure) is detected based on the resistance change of the differential pressure sensor due to the pressure.

The movement mechanism 20 moves the pressure sensor 10 along a predetermined movement path relative to the posture detection unit 100. For example, the moving mechanism 20 moves the pressure sensor 10 in a circular shape using the predetermined movement path. That is, the moving mechanism 20 moves the pressure sensor 10 on the same plane.
The moving mechanism 20 includes a rotating plate 21, a motor control unit 22, and a motor 23. The moving mechanism 20 moves the pressure sensor 10 in a circular shape by rotating the rotating plate 21.

The rotating plate 21 (an example of a rotating body) is provided with a pressure sensor 10 and a magnet 31 to be described later, and is rotated by a motor 23 around a rotation axis C1 (center axis) in the X-axis direction at a predetermined rotation speed. As shown in FIG. 5, the rotating plate 21 is arranged orthogonal to a horizontal plane (XY plane), and a plane on which the pressure sensor 10 moves is a YZ plane.
The motor control unit 22 includes, for example, a motor driver and controls the motor 23. The motor control unit 22 rotates the rotating plate 21 at a predetermined rotation speed, and moves the pressure sensor 10 in a circular shape.
The motor 23 is connected to the rotary plate 21 via the rotary shaft C <b> 1 and rotates the rotary plate 21. Moreover, the motor 23 shall be fixed to the attitude | position detection unit 100, for example.

The magnet 31 is disposed in the vicinity of the circumference of the rotating plate 21 and is used for detecting the rotational position of the pressure sensor 10 (or the rotating plate 21).
The rotation detection unit 32 (an example of a movement information detection unit) detects movement information of the pressure sensor 10. The movement information of the pressure sensor 10 is, for example, information such as a movement position (rotation position), a movement amount, a speed, a direction, and a phase of the pressure sensor 10, and here, as an example, the rotation of the pressure sensor 10 This will be described as information indicating the position (rotational position information). The rotation detection unit 32 is, for example, a magnetic detection element such as a Hall element, and detects the reference position of the rotation plate 21 when the magnet 31 disposed on the rotation plate 21 approaches and outputs a detection signal.

  The synchronous clock signal generation unit 33 (an example of a reference signal generation unit) generates a synchronous clock signal (reference signal) corresponding to a tilt in a predetermined direction based on the movement information detected by the rotation detection unit 32. That is, the synchronous clock signal generation unit 33 generates, for example, a synchronous clock signal for synchronously detecting an inclination in the X-axis direction based on the detection signal output from the rotation detection unit 32 according to the reference position of the rotary plate 21. . Specifically, the synchronous clock signal generation unit 33 generates a clock signal having the same cycle as the rotation cycle of the rotating plate 21 using the detection signal output from the rotation detection unit 32 as a trigger. Then, the synchronous clock signal generation unit 33 delays the generated clock signal so as to synchronously detect the inclination in the X-axis direction, and outputs the delayed clock signal to the inclination information detection unit 40 as a synchronous clock signal.

The power supply unit 34 generates a power supply voltage for operating the tilt sensor 110 and supplies the generated power supply voltage to each unit. Further, the power supply unit 34 supplies a power supply voltage (power supply power) to the pressure sensor 10 on the rotating plate 21 via the slip ring 35.
The slip ring 35 supplies the power supply voltage (power supply power) generated by the power supply unit 34 to the pressure sensor 10 on the rotating rotating plate 21 and outputs the output signal output from the pressure sensor 10 to the inclination information detection unit. 40 is a signal transmission means for transmitting to 40. By using the slip ring 35, the tilt sensor 110 can appropriately transmit the output signal of the pressure sensor 10 disposed on the rotating rotating plate 21 to the tilt information detection unit 40.

  The inclination information detection unit 40 is a signal processing unit that detects inclination information (for example, the inclination angle θ) of the posture detection unit 100 based on the output of the pressure sensor 10 and the movement information of the pressure sensor 10. That is, the inclination information detection unit 40 detects the inclination information of the posture detection unit 100 based on the movement information of the pressure sensor 10 moved along a predetermined movement path by the movement mechanism 20 and the output of the pressure sensor 10. Here, the tilt information includes, for example, information indicating the tilt angle θ, the level, the presence / absence of tilt, and the like. In the present embodiment, an example in which the inclination information detection unit 40 detects the inclination angle θ of the attitude detection unit 100 will be described as an example.

  In addition, the inclination information detection unit 40 detects the inclination angle θ of the posture detection unit 100 based on, for example, the movement distance of the pressure sensor 10 and the change in the output value of the pressure sensor 10 with respect to the movement distance. For example, the inclination information detection unit 40 performs synchronous detection based on the synchronous clock signal generated by the synchronous clock signal generation unit 33 and the periodic output signal output from the pressure sensor 10, and the result of the synchronous detection is obtained. Based on the above, the inclination angle θ of the posture detection unit 100 is detected. In addition, the tilt information detection unit 40 includes a synchronous detection unit 41 and a tilt angle generation unit 42.

  The synchronous detection unit 41 performs synchronous detection based on the periodic output signal of the pressure sensor 10 described above and the synchronous clock signal generated by the synchronous clock signal generation unit 33. The synchronous detection unit 41 includes, for example, a lock-in amplifier circuit and a low-pass filter (LPF), and generates a DC signal proportional to the amplitude of the output signal of the pressure sensor 10.

The inclination angle generation unit 42 generates the inclination angle θ as inclination information based on a DC signal proportional to the amplitude of the output signal of the pressure sensor 10 generated by the synchronous detection unit 41 described above. The inclination angle generation unit 42 generates the amount of change in the height of the pressure sensor 10 based on, for example, a DC signal proportional to the amplitude of the output signal of the pressure sensor 10, and the amount of change in the generated height will be described later. Based on the rotation radius of the pressure sensor 10, the inclination angle θ of the posture detection unit 100 is generated. Further, the inclination angle generation unit 42 outputs information indicating the generated inclination angle θ as inclination information.
The details of the principle of detection of the tilt angle θ by the synchronous detector 41 and the tilt angle generator 42 will be described later with reference to FIGS.

Next, the operation of the posture detection unit 100 according to the present embodiment will be described with reference to the drawings.
FIG. 6 is a diagram illustrating an example of use of the posture detection unit 100 according to the present embodiment.
As shown in this figure, posture detection unit 100 is used by being attached to user U1. In the example shown in this figure, the posture detection unit 100 is mounted on the abdomen BD of the user U1, and measures the posture and motion when the user U1 walks. The posture detection unit 100 measures, for example, the walking posture of the user U1 and outputs an alarm (alarm) to the output unit 113 when a posture exceeding a predetermined tilt range is detected.

  For example, the posture detection unit 100 measures the tilt angle θ of the posture detection unit 100 detected by the tilt sensor 110 as information indicating the posture of the user U1. That is, the measurement control unit 131 of the posture detection unit 100 periodically acquires the tilt angle θ from the tilt sensor 110, and measures the tilt angle θ as information indicating the posture of the user U1. Further, the measurement control unit 131 stores the time information and the acquired inclination angle θ in the measurement data storage unit 121 in association with each other. The change in the tilt angle θ with respect to the time stored in the measurement data storage unit 121 is information indicating the operation.

In addition, the measurement control unit 131 causes the output unit 113 to output an alarm when the acquired inclination angle θ exceeds a reference range (for example, a walking posture range) stored in the reference value storage unit 122. Thereby, posture detection unit 100 can notify user U1 that it deviated from the right walking posture. Details of the operation of the posture detection unit 100 (measurement control unit 131) as described with reference to FIG. 6 will be described later.
Here, first, the principle of detection of the tilt angle θ by the tilt sensor 110 (synchronous detection unit 41 and tilt angle generation unit 42) will be described with reference to FIGS.

FIG. 7 is a diagram illustrating an example of the operation of the synchronous detection unit 41 in the present embodiment.
In this figure, the vertical axis of each graph indicates the voltage of each output signal, and the horizontal axis of each graph indicates time. A waveform W1, a waveform W3, and a waveform W4 indicate the waveforms of the output signal of the pressure sensor 10, the output signal after synchronous detection, and the output signal of the LPF, respectively, in a state where the waveform is not inclined. A waveform W2 represents the synchronous clock signal output from the synchronous clock signal generation unit 33. In addition, broken line waveforms W5 to W7 indicate the waveforms of the output signal of the pressure sensor 10, the output signal after synchronous detection, and the output signal of the LPF, respectively, in the state of being inclined by the inclination angle θ. .

FIG. 8 is a diagram illustrating an example of the operation of the inclination sensor 110 according to the present embodiment.
The example illustrated in FIG. 8 illustrates a state in which the posture detection unit 100 attached to the abdomen BD of the user U1 is inclined by the inclination angle θ in the X-axis direction. In this case, the rotating plate 21 of the inclination sensor 110 is inclined by the inclination angle θ from the Z-axis direction. In addition, when the attitude | position detection unit 100 is not inclined, the rotating plate 21 will be in the state parallel to the Z-axis direction orthogonal to a horizontal surface.

When the tilt sensor 110 detects tilt information, first, the motor control unit 22 of the moving mechanism 20 drives the motor 23 to rotate at a predetermined rotation speed. The motor 23 rotates the rotating plate 21 via the rotating shaft C1. When the rotating plate 21 rotates, the pressure sensor 10 and the magnet 31 arranged on the rotating plate 21 move in a circular shape at a predetermined rotation speed.
In this state, the pressure sensor 10 outputs a sinusoidal output signal like the waveform W1 of FIG.

  The rotation detection unit 32 detects the reference position of the rotating plate 21 and outputs a detection signal when the magnet 31 disposed on the rotating plate 21 approaches. And the synchronous clock signal generation part 33 produces | generates a synchronous clock signal, using the detection signal output from the rotation detection part 32 as a trigger, for example, synchronously detects the inclination of a X-axis direction, and produced | generated the synchronous clock signal Is output to the inclination information detector 40 (see waveform W2 in FIG. 7).

  Further, since the waveform W1 of the output signal of the pressure sensor 10 and the waveform W2 of the synchronous clock signal are in phase, the synchronous detector 41 outputs an output as shown by the waveform W3 as a result of the synchronous detection. Generate a signal. The synchronous detection unit 41 uses the pressure as the synchronous detection because, for example, the synchronous clock signal is in the H state (High state: High state) in the period from time T0 to time T1 and in the period from time T2 to time T3. The output signal of the sensor 10 is multiplied by “+1” to generate a synchronous detection execution result. In addition, the synchronous detection unit 41, for example, in the period from time T1 to time T2 and in the period from time T3 to time T4, the synchronous clock signal is 0 V (Low state: low state). The output signal is multiplied by “−1” and generated as an execution result of the synchronous detection. Thereby, the synchronous detection part 41 produces | generates the output signal after synchronous detection as shown to the waveform W3 as an execution result of synchronous detection.

  Further, the synchronous detection unit 41 removes a component having a predetermined frequency or higher from the output signal after synchronous detection as shown by a waveform W3 in FIG. A DC voltage signal proportional to the amplitude of the output signal of the pressure sensor 10 is generated.

  Further, as in the example illustrated in FIG. 8, when the posture detection unit 100 is inclined by the inclination angle θ in the X-axis direction, the pressure sensor 10 outputs an output signal such as a waveform W <b> 5 in FIG. 7. In this case, since the angle is inclined by the inclination angle θ, the amplitude of the waveform W5 is smaller than the waveform W1 corresponding to the inclination angle θ. Here, assuming that the amount of change between peaks of the output signal of the waveform W5 is the amount of change ΔVo, for example, the amount of change ΔVo decreases as the tilt angle θ increases.

Further, when the state is inclined by the inclination angle θ, the synchronous detection unit 41 generates an output signal after synchronous detection as shown by a waveform W6 in FIG. 7, and the waveform of FIG. 7 is obtained by a low pass filter (LPF). A signal having a DC voltage V0 proportional to the change amount ΔVo as indicated by W7 is generated.
Note that the tilt angle θ in the X-axis direction shown in FIG. 8 is expressed by the following equation (1).

  Here, as shown in FIG. 8, the angle β is an angle of the rotating surface of the rotating plate 21 with respect to the horizontal plane. The variable Rs indicates the rotation radius of the pressure sensor 10. Further, (change in height corresponding to the change amount ΔVo) is obtained by converting the change amount ΔVo of the output signal of the pressure sensor 10 into a change in height in the Z-axis direction. For example, the inclination angle generation unit 42 may convert (a change in height corresponding to the change amount ΔVo) from the change amount ΔVo by calculation, or a conversion table in which the change amount ΔVo is associated with a change in height. (A change in height corresponding to the change amount ΔVo) may be generated.

The inclination angle generation unit 42 converts, for example, the above-described DC voltage V0 generated by the synchronous detection unit 41 (change in height corresponding to the change amount ΔVo), and converts (the height corresponding to the change amount ΔVo). Change) and the above-described equation (1), the inclination angle θ is generated as inclination information.
In the above-described example, the case where the tilt angle θ is tilted in the X-axis direction has been described, but the DC voltage output by the synchronous detection unit 41 is also shown in FIG. As with the waveform W7 of FIG. For this reason, the tilt angle generation unit 42 can generate the tilt angle θ even when tilted in the other direction by the tilt angle θ, as in the case of tilting in the X axis direction by the tilt angle θ.

  As described above, the inclination angle generation unit 42 detects the inclination angle θ of the posture detection unit 100 using the execution result of the synchronous detection executed by the synchronous detection unit 41 and the above-described equation (1). The posture detection unit 100 measures the tilt angle θ detected by the tilt sensor 110 as information indicating the posture of the user U1.

Next, the operation of the posture detection unit 100 will be described with reference to FIG.
FIG. 9 is a flowchart showing an example of the operation of the posture detection unit 100 in the present embodiment.
As shown in FIG. 9, the posture detection unit 100 first starts the operation of the tilt sensor 110 (step S101). The measurement control unit 131 of the posture detection unit 100 causes the motor control unit 22 of the tilt sensor 110 to rotate the motor 23 to start detecting the tilt angle θ.

  Next, the measurement control unit 131 determines whether or not alarm notification is necessary (step S102). For example, the measurement control unit 131 acquires information on whether or not the alarm notification received by the operation unit 111 is necessary, and determines whether or not alarm notification is necessary based on the acquired information. To do. The measurement control unit 131 advances the process to step S103 when it is necessary to notify an alarm (step S102: YES). Moreover, the measurement control part 131 advances a process to step S109, without the need of alarm notification (step S102: NO).

  In step S103, the measurement control unit 131 selects a notification mode (hereinafter referred to as a notification mode). The measurement control unit 131 acquires information indicating the notification mode selected by the user U1 via the operation unit 111, and selects the notification mode. The notification mode includes, for example, the following modes (A) to (E).

(A) A mode for notifying an alarm indicating that the inclination angle θ has become the first threshold value when the inclination angle θ is equal to the first threshold value stored in the reference value storage unit 122.
(B) A mode for notifying an alarm indicating that the tilt information is equal to or greater than the second threshold when the tilt angle θ is equal to or greater than the second threshold stored in the reference value storage unit 122.
(C) A mode for notifying an alarm indicating that the tilt information is equal to or smaller than the third threshold value when the tilt angle θ is equal to or smaller than the third threshold value stored in the reference value storage unit 122.
(D) When the inclination angle θ is out of the reference range, which is a range between the reference range upper limit value and the reference range lower limit value stored in the reference value storage unit 122, it indicates that the inclination angle θ is out of the reference range. Mode to notify the alarm.
(E) When the inclination angle θ falls within the reference range that is the range between the reference range upper limit value and the reference range lower limit value stored in the reference value storage unit 122, it indicates that the inclination angle θ is within the reference range. Mode to notify the alarm.

  Next, the measurement control unit 131 executes a setting branch according to the notification mode (step S104). When the notification mode is the target value setting (when one threshold value is set), the measurement control unit 131 advances the process to step S105. That is, the measurement control part 131 advances a process to step S105, when notification mode is (A)-(C) mentioned above. Moreover, the measurement control part 131 advances a process to step S106, when notification mode is range setting (in the case of the reference range setting which sets several values). That is, the measurement control part 131 advances a process to step S106, when notification mode is (D) and (E) mentioned above.

  In step S105, the measurement control unit 131 sets a target value. For example, the measurement control unit 131 acquires a target value (for example, a first threshold value, a second threshold value, or a third threshold value) from the user U1 via the operation unit 111, and uses the acquired target value as a reference value. The data is stored in the storage unit 122. After the process of step S105, the measurement control unit 131 advances the process to step S108.

In step S106, the measurement control unit 131 sets an upper limit value. For example, the measurement control unit 131 acquires an upper limit value (for example, a reference range upper limit value) from the user U1 via the operation unit 111, and stores the acquired upper limit value in the reference value storage unit 122.
Next, the measurement control unit 131 sets a lower limit value (step S107). For example, the measurement control unit 131 acquires a lower limit value (for example, a reference range lower limit value) from the user U1 through the operation unit 111, and stores the acquired lower limit value in the reference value storage unit 122. After the process of step S106, the measurement control unit 131 advances the process to step S108.

  In step S108, the measurement control unit 131 enables the notification setting. For example, the measurement control unit 131 changes information (for example, flag information) that enables alarm notification in the storage unit 120 to enable notification setting. In the present embodiment, for example, for each of the notification modes (A) to (E) described above, the notification setting can be enabled or disabled, and the measurement control unit 131 is selected, for example. Enable notification settings for each notification mode. After the process of step S108, the measurement control unit 131 advances the process to step S110.

  In step S109, the measurement control unit 131 invalidates the notification setting. For example, the measurement control unit 131 changes information (for example, flag information) that enables alarm notification in the storage unit 120 and invalidates the notification setting.

  Next, in step S110, the measurement control unit 131 determines whether or not measurement is started. For example, the measurement control unit 131 determines whether or not to start measurement based on whether or not the operation unit 111 has been operated by the user U1 to indicate that measurement is to be started. The measurement control part 131 advances a process to step S111, when it is measurement start (step S110: YES). Moreover, the measurement control part 131 returns a process to step S110, when measurement is not started (step S110: NO).

In step S <b> 111, the measurement control unit 131 acquires the tilt angle from the tilt sensor 110 and stores the tilt angle in the measurement data storage unit 121. That is, the measurement control unit 131 acquires the inclination angle θ from the inclination sensor 110, and stores the acquired inclination angle θ (θ _M ) and time (t) in the measurement data storage unit 121 in association with each other. Thereby, the measurement data storage unit 121 stores an operation pattern (θ (t)) indicating a change of the tilt angle θ with respect to time.

  Next, the measurement control unit 131 determines whether or not the alarm notification setting is valid (step S112). The measurement control unit 131 determines whether or not the alarm notification setting is valid based on information (for example, flag information) that enables the alarm notification stored in the storage unit 120. If the alarm notification setting is valid (step S112: YES), the measurement control unit 131 advances the process to step S113. In addition, when the alarm notification setting is not valid (invalid) (step S112: NO), the measurement control unit 131 advances the process to step S115.

  In step S113, the measurement control unit 131 determines whether or not the alarm notification condition is satisfied. That is, the measurement control unit 131 determines whether or not the above-described notification modes (A) to (E) are satisfied. If the condition for alarm notification is satisfied (step S113: YES), the measurement control unit 131 advances the process to step S114. Moreover, the measurement control part 131 advances a process to step S115, when the conditions for alarm notification are not satisfied (step S113: NO).

  In step S114, the measurement control unit 131 outputs an alarm. For example, the measurement control unit 131 causes the output unit 113 to output an alarm. Note that the measurement control unit 131 may change the alarm and notify the user U1 according to the notification modes (A) to (E) described above. That is, the measurement control unit 131 may change the sound, light, and vibration patterns as alarms according to the notification modes (A) to (E), for example.

  In step S115, the measurement control unit 131 determines whether the measurement is finished. For example, the measurement control unit 131 determines whether or not the measurement is finished depending on whether or not the operation unit 111 has been operated by the user U1 to indicate that the measurement is to be finished. The measurement control part 131 complete | finishes a process, when it is completion | finish of measurement (step S115: YES). Moreover, the measurement control part 131 returns a process to step S111, and repeats a measurement, when measurement is not complete | finished (step S115: NO).

  As described above, the posture detection unit 100 measures the posture and motion of the user U1 based on the tilt angle θ detected by the tilt sensor 110, and when the alarm notification condition is satisfied, the alarm is detected by the user U1. Notify

As described above, the posture detection unit 100 according to the present embodiment is based on the inclination sensor 110 that detects inclination information (for example, the inclination angle θ) of the device itself and the inclination information detected by the inclination sensor 110. And a measurement control unit 131 that measures operation information related to the operation of U1 (measurement target person). Here, the motion information related to the motion of the user U1 includes information indicating the posture and motion of the user U1. That is, the motion information includes information indicating the posture or motion of the subject to which the apparatus is attached.
And the inclination sensor 110 is arrange | positioned so that a movement with respect to an own apparatus is relatively possible, and is provided with the pressure sensor 10 and the inclination information detection part 40 which detect the pressure (for example, atmospheric | air pressure) of a fluid. The inclination information detection unit 40 detects inclination information (for example, the inclination angle θ) based on the output of the pressure sensor 10 and the movement information of the pressure sensor 10.
Accordingly, in the posture detection unit 100 according to the present embodiment, for example, the tilt sensor 110 detects tilt information (for example, the tilt angle θ) based on the pressure, and based on the tilt information, the posture and operation of the user U1. Therefore, the motion information (for example, the posture and motion of the user U1) can be accurately measured without being affected by the inertial force.

  For example, since the posture detection unit 100 according to the present embodiment can detect the tilt information by using at least one pressure sensor 10, the detection accuracy does not deteriorate due to, for example, variations among the plurality of pressure sensors 10. Further, the posture detection unit 100 is not affected by the acceleration in the horizontal direction due to the operation of the user U1 as compared with the case where the acceleration sensor is provided. Furthermore, the posture detection unit 100 detects angular velocity by a gyro sensor (angular velocity sensor), and does not need to perform integration processing and reduces error accumulation compared to the case of detecting inclination information based on the angular velocity. Can do. From these things, the attitude | position detection unit 100 can improve the detection precision of inclination information. The posture detection unit 100 according to the present embodiment includes the posture detection unit 100 that can detect the tilt information with high accuracy, and thus motion information (for example, the posture and motion of the user U1) without being affected by inertial force. Can be measured accurately.

Moreover, in this embodiment, the inclination sensor 110 is provided with the moving mechanism 20 which moves the pressure sensor 10 with a predetermined | prescribed movement path | route with respect to an own apparatus. The inclination information detection unit 40 is based on the movement information of the pressure sensor 10 moved along a predetermined movement path (for example, the path of the rotational movement on the plane of the rotating plate 21) by the movement mechanism 20 and the output of the pressure sensor 10. Thus, tilt information (for example, tilt angle θ) is detected.
Accordingly, since the pressure sensor 10 moves along a predetermined movement path, the inclination sensor 110 according to the present embodiment easily detects the movement distance of the pressure sensor 10 by detecting position information (for example, rotation position information). It becomes possible to calculate. That is, the inclination sensor 110 can simplify the calculation of movement information. Therefore, the posture detection unit 100 according to the present embodiment can accurately measure the movement information (for example, the posture and movement of the user U1) without being influenced by the inertial force while simplifying the calculation of the movement information. .

In the present embodiment, the moving mechanism 20 includes a rotating plate 21 (rotating body) on which the pressure sensor 10 is disposed, and moves the pressure sensor 10 in a circular shape by rotating the rotating plate 21. The inclination information detection unit 40 performs synchronous detection based on a periodic output signal output from the pressure sensor 10 while being moved along a predetermined movement path and a reference signal (for example, a synchronous clock signal) based on the movement information. Then, tilt information (for example, tilt angle θ) is detected based on the result of the synchronous detection.
Thereby, since the inclination sensor 110 uses synchronous detection, the detection process of the inclination information of an own apparatus can be simplified. Therefore, since the posture detection unit 100 according to the present embodiment can further simplify the calculation of movement information, the measurement of motion information (for example, the posture and motion of the user U1) can be further simplified.

Further, in the present embodiment, the measurement control unit 131 determines whether or not the inclination information detected by the inclination information detection unit 40 is within a predetermined reference range, and based on the determination result, notification regarding operation information. Is output to the output unit 113.
As a result, the posture detection unit 100 according to the present embodiment, when the posture or motion of the user U1 reaches the target posture or motion, or the posture or motion of the user U1 deviates from the target posture or motion. In this case, an alarm (warning) can be appropriately notified to the user U1.
For example, in the example shown in FIG. 6, when the walking posture of the user U1 deviates from the target posture, an alarm is notified, or the posture of the pedestrian (user U1) collapses and there is a risk of falling. In some cases, an alarm can be notified.

In the present embodiment, the measurement control unit 131 outputs an alarm indicating that the inclination information has reached the first threshold when the inclination information is equal to the first threshold value as a notification regarding the operation information. To output.
Thereby, the posture detection unit 100 according to the present embodiment can appropriately notify the user U1 that the posture or motion of the user U1 has reached the target posture or motion.

Moreover, in this embodiment, the measurement control part 131 outputs the alarm which shows that inclination information became more than a 2nd threshold value as notification regarding operation information, when inclination information is more than a 2nd threshold value. Output to the unit 113. Moreover, in this embodiment, the measurement control part 131 outputs the alarm which shows that inclination information became below the 3rd threshold value as notification regarding operation information, when inclination information is below the 3rd threshold value. Output to the unit 113.
Thereby, the posture detection unit 100 according to the present embodiment can appropriately notify the user U1 that the posture or motion of the user U1 has deviated from the target posture or motion.

Further, in the present embodiment, the measurement control unit 131 outputs an alarm indicating that the inclination information is out of the predetermined reference range as the notification regarding the operation information when the inclination information is not within the predetermined reference range. 113 to output.
Thereby, the posture detection unit 100 according to the present embodiment can appropriately notify the user U1 that the posture or motion of the user U1 is out of the target range of the posture or motion.

In the present embodiment, the measurement control unit 131 outputs an alarm indicating that the inclination information is within the predetermined reference range as the notification regarding the operation information when the inclination information is within the predetermined reference range. To output.
Thereby, the posture detection unit 100 according to the present embodiment can appropriately notify the user U1 that the posture or motion of the user U1 is within the posture or motion target range.

[Second Embodiment]
Next, a posture detection unit 100a according to a second embodiment will be described with reference to the drawings.
FIG. 10 is a block diagram illustrating an example of a posture detection unit 100a according to the second embodiment.
As shown in FIG. 10, the posture detection unit 100a includes a tilt sensor 110a, an operation unit 111, a display unit 112, an output unit 113, a communication unit 114, a storage unit 120a, and a control unit 130a. Yes.
In this figure, the same components as those shown in FIG. 2 are denoted by the same reference numerals, and the description thereof is omitted.

  In the present embodiment, the tilt sensor 110a detects tilt information in the biaxial direction of the tilt angle θx in the X-axis direction and the tilt angle θy in the Y-axis direction, and the control unit 130a further notifies the alarm. The mode is different from the first embodiment in that an alarm is notified as a mode according to a comparison result between an operation pattern indicating a change in inclination information with respect to time and a target operation pattern (reference operation pattern).

The tilt sensor 110a performs synchronous detection based on the periodic output signal output from the pressure sensor 10 and the first synchronous clock signal (first reference signal), and the same periodic output signal. Then, synchronous detection is executed based on the second synchronous clock signal (second reference signal). The tilt sensor 110a detects the tilt angle θx and the tilt angle θy based on the execution results of these two synchronous detections. The first synchronous clock signal is a clock signal generated so as to synchronously detect the inclination in the X-axis direction, as in the first embodiment. The second synchronous clock signal is a clock signal that is 90 degrees out of phase with the first synchronous clock signal.
Details of the tilt sensor 110a will be described later.

The storage unit 120a stores various types of information used for processing executed by the posture detection unit 100a. The storage unit 120 a includes a measurement data storage unit 121, a reference value storage unit 122, and an operation pattern storage unit 123.
The measurement data storage unit 121 in this embodiment is basically the same as that in the first embodiment. For example, the tilt angle θx and the tilt angle θy are stored as tilt information in association with time information. .
In the reference value storage unit 122 according to the present embodiment, each threshold value and reference range are expanded to the inclination angle θx and the inclination angle θy, similarly to the measurement data storage unit 121. The reference value storage unit 122 may further store information indicating a threshold value for notifying an alarm and a reference range in accordance with a comparison result based on an operation pattern described later.

  The operation pattern storage unit 123 stores an operation pattern serving as a reference (target). Here, the operation pattern indicates a change in the tilt information with respect to time. For example, as with the measurement result stored in the measurement data storage unit 121, the time information is associated with the tilt angle θx and the tilt angle θy. Information. The operation pattern storage unit 123 stores a reference pattern serving as a reference (target) for a predetermined operation pattern. The operation pattern storage unit 123 may store a plurality of reference patterns.

The control unit 130a is, for example, a processor including a CPU and the like, and comprehensively controls the posture detection unit 100a. The control unit 130a includes, for example, a measurement control unit 131a.
The measurement control unit 131a measures motion information (for example, information indicating posture and motion) regarding the motion of the user U1 based on the tilt information (the tilt angle θx and the tilt angle θy) detected by the tilt sensor 110a. The measurement control unit 131a periodically acquires the inclination angle θx and the inclination angle θy detected by the inclination sensor 110a, associates the acquired inclination angle θx and inclination angle θy with time information, and stores the measurement data storage unit 121. Remember me.

In addition, the measurement control unit 131a detects that the inclination angle θx detected by the inclination sensor 110a is based on the reference value stored in the reference value storage unit 122 based on the inclination angle θx and the inclination angle θy detected by the inclination sensor 110a. It is determined whether the notification condition is satisfied, and the output unit 113 outputs an alarm according to the determination result.
In addition, the measurement control unit 131a compares the operation pattern based on the inclination angle θx and the inclination angle θy with the reference pattern stored in the operation pattern storage unit 123, and outputs an alarm to the output unit 113 based on the comparison result. Let For example, similarly to the posture, the measurement control unit 131a may cause the output unit 113 to output an alarm based on the threshold value or the reference range stored in the reference value storage unit 122 in the operation pattern. In this case, the threshold value may be, for example, a value of a predetermined ratio (for example, + 5%) of the reference value stored in the operation pattern storage unit 123, and the reference range may be, for example, the operation pattern storage unit 123. It may be a predetermined range of reference values to be stored (for example, ± 5 degrees, ± 10%, etc.).

Next, the configuration of the tilt sensor 110a according to the present embodiment will be described with reference to FIG.
FIG. 11 is a block diagram illustrating an example of the tilt sensor 110a according to the present embodiment.
As shown in FIG. 11, the inclination sensor 110 a includes a pressure sensor 10, a moving mechanism 20, a magnet 31, a rotation detection unit 32, a synchronous clock signal generation unit 33 a, a power supply unit 34, a slip ring 35, And an inclination information detection unit 40a.
In this figure, the same components as those shown in FIG. 5 are denoted by the same reference numerals, and the description thereof is omitted.

  In the present embodiment, the synchronous clock signal generation unit 33a generates the first synchronous clock signal (CLKA) so as to synchronously detect the inclination in the X-axis direction, and has a 90-degree phase with the first synchronous clock signal. The shifted second synchronous clock signal (CLKB) is generated.

The inclination information detection unit 40a includes a synchronous detection unit 41a and an inclination angle generation unit 42a.
The synchronous detection unit 41a performs synchronous detection based on the output signal of the pressure sensor 10 and the first synchronous clock signal, and synchronizes based on the output signal of the pressure sensor 10 and the second synchronous clock signal. Perform detection.
The inclination angle generation unit 42a generates the inclination angle θx and the inclination angle θy based on the execution results of the two synchronous detections executed by the synchronous detection unit 41a. For example, the inclination angle generation unit 42a detects the inclination angle θx (inclination information in the first direction) in the X-axis direction based on the execution result of the synchronous detection based on the first synchronous clock signal, and the second Based on the execution result of the synchronous detection based on the synchronous clock signal, the inclination angle θy in the Y-axis direction (inclination information in the second direction) is detected.

Next, with reference to FIGS. 12 and 13, an operation of generating the inclination angle θx and the inclination angle θy of the inclination information detection unit 40a according to the present embodiment will be described.
FIG. 12 is a diagram illustrating an example of the operation of the synchronous detection unit 41a according to the present embodiment.
In this figure, the vertical axis of each graph indicates the voltage of each output signal, and the horizontal axis of each graph indicates time. In addition, the waveform W8, the waveform W11, and the waveform W12 are sequentially generated by the output signal of the pressure sensor 10, the output signal A1 of the LPF after synchronous detection by the synchronous clock signal CLKA, and the synchronous clock signal CLKB in a state where the waveform is not inclined. Each waveform of the output signal B1 of the LPF after the synchronous detection is shown. A waveform W9 represents the synchronous clock signal CLKA output from the synchronous clock signal generation unit 33, and a waveform W10 represents the synchronous clock signal CLKB output from the synchronous clock signal generation unit 33.

The synchronous clock signal CLKA and the synchronous clock signal CLKB are 90 degrees out of phase. For example, the synchronous clock signal CLKA shown in the waveform W9 is a period in which the period from time T10 to time T12 and the period from time T14 to time T16 are in the H state. The synchronous clock signal CLKB indicated by the waveform W10 that is 90 degrees out of phase is a period in which the period from time T11 to time T13 and the period from time T15 to time T17 are in the H state.
The broken line waveforms W13 to W15 are, in order, the output signal A1 of the pressure sensor 10 after the synchronous detection by the synchronous clock signal CLKA, the output signal of the pressure sensor 10 in the state inclined by the inclination angle θy in the Y-axis direction, The waveforms of the LPF output signal B1 after synchronous detection by the synchronous clock signal CLKB are shown.

FIG. 13 is a diagram illustrating an example of the operation of the inclination sensor 110a according to the present embodiment.
The example shown in FIG. 13 shows a state in which the posture detection unit 100a attached to the abdomen BD of the user U1 is inclined by the inclination angle θy in the Y-axis direction. In this case, the rotating plate 21 of the inclination sensor 110a is equivalent to a state in which the rotation plate 21 is rotated by the inclination angle θy about the rotation axis C1.

  First, as shown in FIG. 12, the pressure sensor 10 outputs an output signal as shown by a waveform W8, and the synchronous detection unit 41a outputs the output signal and the synchronous clock signal generation unit 33, as shown in FIG. Synchronous detection is executed with the synchronous clock signal CLKA shown in the waveform W9 generated by, and an output signal A1 as shown in the waveform W11 is output. In addition, the synchronous detection unit 41a performs synchronous detection using the output signal of the pressure sensor 10 and the synchronous clock signal CLKB indicated by the waveform W10 generated by the synchronous clock signal generation unit 33, and an output signal as indicated by the waveform W12. B1 is output. Note that, in the non-tilted state, since the tilt angle θy is 0 degree in the Y-axis direction, the DC voltage of the output signal of the waveform W12 is 0 V (volt).

  Next, in a state where the tilt angle θy is tilted in the Y-axis direction (tilt angle θx = 0 ° in the X-axis direction), as shown in FIG. 12, the pressure sensor 10 outputs an output signal as indicated by a broken line waveform W13. Is output. In this case, the output signal of the pressure sensor 10 is a signal whose phase is shifted by the inclination angle θy from the output signal (waveform W8) in a state where the pressure sensor 10 is not inclined, and the amplitude thereof does not change. Therefore, the amount of change ΔVo between the peaks of the output signal shown in the waveform W13 is the same as the output signal (waveform W8) in the non-tilt state.

  Further, in a state where the inclination is inclined by the inclination angle θy in the Y-axis direction, the synchronous detection unit 41a outputs a signal of the DC voltage V1 as shown by a broken line waveform W14 as a result of executing synchronous detection by the synchronous clock signal CLKA. . The signal of the DC voltage V1 shown in this waveform W14 is a signal whose voltage has dropped from the output signal (waveform W11) in a non-tilt state in accordance with the tilt angle θy in the Y-axis direction. Note that since only the signal of the DC voltage V1 shown in the waveform W14 is indistinguishable from the case of tilting in the X-axis direction, in this embodiment, the synchronous detection unit 41a executes synchronous detection using the synchronous clock signal CLKB. .

  The synchronous detection unit 41a outputs a signal of the DC voltage V2 as indicated by a broken line waveform W15 as a result of executing synchronous detection by the synchronous clock signal CLKB. The signal of the DC voltage V2 shown in the waveform W15 is a signal whose voltage has increased in accordance with the inclination angle θy in the Y-axis direction from the output signal (waveform W12) that is not inclined. Note that the DC voltage V1 and the DC voltage V2, which are execution results of synchronous detection, are expressed by the following equation (2).

Here, the variable α is a proportional coefficient.
Further, based on the above-described equation (2), the inclination angle θy in the Y-axis direction is expressed by the following equation (3).

The inclination angle θy in the Y-axis direction is calculated by dividing the direct-current voltage V2 by the direct-current voltage V1 and calculating the inverse tangent function as shown in equation (3).
The inclination angle generation unit 42a generates the inclination angle θy based on the execution result (DC voltage V1 and DC voltage V2) of the synchronous detection by the synchronous detection unit 41a using the above-described equation (3).

  Further, the change amount ΔVo is expressed by the following equation (4) by the inclination angle θy calculated by the equation (3) and the above-described equation (2).

The inclination angle generation unit 42a calculates the change amount ΔVo using the equation (4), and further uses the equation (1) to calculate the inclination angle θx in the X-axis direction, as in the first embodiment. Is calculated. In the example shown in FIG. 12, since the tilt angle θx in the X-axis direction is 0 degree, the tilt angle generation unit 42a uses the formulas (4) and (1) to set the tilt angle θx. = 0 degree is generated.
In the example shown in FIGS. 12 and 13, the example in which the tilt angle θy is tilted in the Y-axis direction has been described, but even when the tilt angle θx is tilted in the X direction and the tilt angle θy is tilted in the Y-axis direction, The tilt angle generation unit 42a uses the synchronous detection execution result (DC voltage V1 and DC voltage V2) by the synchronous detection unit 41a and Formula (3), Formula (4), and Formula (1) to It is possible to generate θx and tilt angle θy.

As described above, in the posture detection unit 100a (information measuring apparatus) according to the present embodiment, the inclination information is orthogonal to the inclination angle θx in the X-axis direction (inclination information in the first direction) and the X-axis direction. And an inclination angle θy in the Y-axis direction (inclination information in the second direction). The inclination information detection unit 40a performs synchronous detection based on the periodic output signal of the pressure sensor 10 and the synchronous clock signal CLKA (first reference signal) based on the movement information, and based on the result of the synchronous detection. Thus, the inclination angle θx in the X-axis direction is detected. In addition, the inclination information detection unit 40a performs synchronous detection based on the periodic output signal of the pressure sensor 10 and the synchronous clock signal CLKB (second reference signal) that is 90 degrees out of phase with the synchronous clock signal CLKA. Then, the tilt angle θy in the Y-axis direction is detected based on the result of the synchronous detection.
Thereby, the posture detection unit 100a according to the present embodiment can accurately detect the tilt angle in the biaxial direction by a simple method, and can accurately measure the posture and motion of the user U1.

Further, in the present embodiment, the measurement control unit 131a includes an operation pattern indicating a change in inclination information (for example, the inclination angle θx and the inclination angle θy) with respect to time, and a reference pattern serving as a reference for a predetermined operation pattern. The comparison is performed, and an alarm (notification regarding operation information) is output to the output unit 113 based on the comparison result.
Accordingly, the posture detection unit 100a according to the present embodiment can perform not only simple posture determination but also determination as an operation pattern that is a change with respect to posture time. Therefore, the posture detection unit 100a according to the present embodiment gives an alarm (warning) to the user U1 when the operation pattern of the user U1 matches the target operation pattern or deviates from the target operation pattern. Appropriate notifications can be made.

[Third Embodiment]
Next, a posture detection unit 100b according to a third embodiment will be described with reference to the drawings.
FIG. 14 is a block diagram illustrating an example of a posture detection unit 100b according to the third embodiment.
As shown in FIG. 14, the posture detection unit 100b includes an inclination sensor 110b, an operation unit 111, a display unit 112, an output unit 113, a communication unit 114, a temperature sensor 115, an absolute pressure sensor 116, and a storage. Part 120b and control part 130b.
In this figure, the same components as those shown in FIG. 2 are denoted by the same reference numerals, and the description thereof is omitted.

This embodiment is different from the first embodiment in that the inclination angle θ is corrected based on temperature information detected by the temperature sensor 115 and atmospheric pressure information detected by the absolute pressure sensor 116.
The temperature sensor 115 detects the air temperature around the inclination sensor 110b.
The absolute pressure sensor 116 detects the atmospheric pressure around the tilt sensor 110b.

The storage unit 120b stores various types of information used for processing executed by the posture detection unit 100b. The storage unit 120b includes a measurement data storage unit 121, a reference value storage unit 122, and a correction information storage unit 124.
The correction information storage unit 124 stores, for example, a temperature correction table in which temperature information and temperature correction information are associated, and an atmospheric pressure correction table in which atmospheric pressure information and atmospheric pressure correction information are associated. Here, the temperature correction information and the atmospheric pressure correction information are, for example, a correction coefficient and an offset value for correcting the output of the pressure sensor 10 in the inclination sensor 110b or the execution result of the synchronous detection.

The control unit 130b is, for example, a processor including a CPU and the like, and comprehensively controls the posture detection unit 100b. The control unit 130b includes, for example, a measurement control unit 131b.
The measurement control unit 131b acquires temperature information detected by the temperature sensor 115, and acquires temperature correction information corresponding to the temperature information from the correction information storage unit 124. In addition, the measurement control unit 131b acquires atmospheric pressure information detected by the absolute pressure sensor 116, and acquires atmospheric pressure correction information corresponding to the atmospheric pressure information from the correction information storage unit 124. The measurement control unit 131b outputs the temperature correction information and the atmospheric pressure correction information acquired from the correction information storage unit 124 to the tilt sensor 110b, and causes the tilt sensor 110b to correct the tilt information (for example, the tilt angle θ). The measurement control unit 131b periodically acquires the inclination angle θ from the inclination sensor 110b, associates the acquired inclination angle θ with time information, and stores them in the measurement data storage unit 121. Basic functions other than the function of outputting correction information to the tilt sensor 110b in the measurement control unit 131b are the same as those of the measurement control unit 131 of the first embodiment, and thus the description thereof is omitted here.

The tilt sensor 110b detects the tilt angle θ by executing synchronous detection based on the periodic output signal output from the pressure sensor 10 and the synchronous clock signal (reference signal). The tilt sensor 110b corrects the tilt angle θ based on correction information (temperature correction information and atmospheric pressure correction information) acquired from the measurement control unit 131b.
Next, the configuration of the inclination sensor 110b in the present embodiment will be described with reference to FIG.

FIG. 15 is a block diagram illustrating an example of the tilt sensor 110b according to the present embodiment.
As shown in FIG. 15, the inclination sensor 110 b includes a pressure sensor 10, a moving mechanism 20, a magnet 31, a rotation detection unit 32, a synchronous clock signal generation unit 33, a power supply unit 34, a slip ring 35, And an inclination information detection unit 40b. The inclination information detection unit 40 b includes a synchronous detection unit 41, an inclination angle generation unit 42, a temperature correction unit 43, and an atmospheric pressure correction unit 44.
In FIG. 15, the same components as those shown in FIG. 5 are denoted by the same reference numerals, and the description thereof is omitted.

  The temperature correction unit 43 corrects the inclination information (for example, the inclination angle θ) based on the temperature information detected by the temperature sensor 115. Specifically, the temperature correction unit 43 corrects the inclination angle θ, for example, by correcting the execution result (DC voltage V0) of the synchronous detection unit 41 based on the temperature correction information acquired from the measurement control unit 131b. . Here, the temperature correction information is, for example, a correction coefficient and an offset value, and the temperature correction unit 43 multiplies the DC voltage V0 by the correction coefficient, and further corrects by adding the offset value.

  The atmospheric pressure correction unit 44 corrects the inclination information (for example, the inclination angle θ) based on the atmospheric pressure information detected by the absolute pressure sensor 116. Specifically, the atmospheric pressure correction unit 44 corrects the inclination angle θ by correcting the execution result (DC voltage V0) of the synchronous detection unit 41 based on, for example, the atmospheric pressure correction information acquired from the measurement control unit 131b. to correct. Here, the atmospheric pressure correction information is, for example, a correction coefficient and an offset value, and the atmospheric pressure correction unit 44 multiplies the DC voltage V0 by the correction coefficient, and further corrects by adding the offset value.

The inclination angle generation unit 42 generates the inclination angle θ based on the execution result of the synchronous detection corrected by the temperature correction unit 43 and the atmospheric pressure correction unit 44.
Note that either the correction by the temperature correction unit 43 or the correction by the atmospheric pressure correction unit 44 may be executed first. Further, based on an instruction from the measurement control unit 131b, one of correction by the temperature correction unit 43 and correction by the atmospheric pressure correction unit 44 may be executed.

As described above, the posture detection unit 100b according to the present embodiment includes the temperature sensor 115 that detects the temperature, and the temperature correction that corrects the tilt information (for example, the tilt angle θ) based on the temperature detected by the temperature sensor 115. Part 43.
As a result, the posture detection unit 100b according to the present embodiment can accurately detect inclination information (for example, the inclination angle θ) in accordance with the temperature change, and more accurately detect the posture and operation of the user U1. It can be measured.

In addition, the posture detection unit 100b according to the present embodiment includes an absolute pressure sensor 116 that detects atmospheric pressure, and an atmospheric pressure that corrects inclination information (for example, an inclination angle θ) based on the atmospheric pressure detected by the absolute pressure sensor 116. And a correction unit 44.
Thereby, the posture detection unit 100b according to the present embodiment can accurately detect the inclination information (for example, the inclination angle θ) according to the atmospheric pressure change (for example, change in weather, change in altitude of the place, etc.). This makes it possible to measure the posture and motion of the user U1 more accurately.

[Fourth Embodiment]
Next, a posture detection system 1 according to a fourth embodiment will be described with reference to the drawings.
FIG. 16 is a functional block diagram illustrating an example of the posture detection system 1 according to the fourth embodiment.
As shown in FIG. 16, the posture detection system 1 includes a plurality of posture detection units (100 a-1, 100 a-2,...) And a mobile terminal 200.

  The posture detection units (100a-1, 100a-2,...) Have the same configuration as the posture detection unit 100a described above, and in the present embodiment, indicate any posture detection unit included in the posture detection system 1. If not particularly distinguished, it will be described as the posture detection unit 100a.

  The portable terminal 200 (an example of a control device) is a terminal device such as a smartphone, and controls the posture detection unit 100a. The mobile terminal 200 includes an operation unit 201, a display unit 202, an output unit 203, a communication unit 204, a terminal storage unit 210, and a terminal control unit 220.

The operation unit 201 is an input device such as a switch or a touch panel. The operation unit 201 receives various types of information through operations by the user U1.
The display unit 202 is a liquid crystal display, for example, and displays various information such as an operation screen of the mobile terminal 200 and a message display.
The output unit 203 is, for example, a speaker that outputs sound, a vibration motor that generates vibration, a light emitting diode that generates light, a headphone amplifier that outputs a sound signal for headphones, and the like. For example, the output unit 203 outputs music for dance or outputs an alarm to the user U1 in the same manner as the posture detection unit 100a.

The communication unit 204 communicates with the posture detection unit 100a by wireless communication such as Bluetooth (registered trademark) or wireless LAN.
The terminal storage unit 210 stores various information used for processing executed by the mobile terminal 200. The terminal storage unit 210 includes a unit information storage unit 211, an operation pattern storage unit 212, and an operation data storage unit 213.

  The unit information storage unit 211 stores information for managing the posture detection unit 100a that cooperates with the mobile terminal 200 in the posture detection system 1. For example, as illustrated in FIG. 17, the unit information storage unit 211 stores “unit ID”, “mounting location”, and “alarm” in association with each other.

FIG. 17 is a diagram illustrating a data example of the unit information storage unit 211 according to the present embodiment.
In this figure, “unit ID” indicates identification information for identifying the posture detection unit 100a. Further, the “wearing place” indicates a part of the user U1 to which the posture detection unit 100a is attached. “Alarm” indicates a sound pattern when an alarm is notified to the user U1 from the posture detection unit 100a.
In the example illustrated in FIG. 17, for example, the posture detection unit 100a whose “unit ID” is “001” is attached to the “right thigh” of the user U1 and “alarm” is “A pattern”. ing.
The unit information storage unit 211 may store reference value information such as various threshold values and reference ranges in addition to “alarm”.

Returning to the description of FIG. 16, the motion pattern storage unit 212 stores a motion pattern (a reference pattern of a plurality of parts) serving as a target (reference) in which a plurality of posture detection units 100 a cooperate. For example, the operation pattern storage unit 212 stores time information in association with the inclination angle θx and the inclination angle θy for each attachment location (attachment site).
FIG. 18 is a diagram illustrating an example of data in the operation pattern storage unit 212 in the present embodiment.
In FIG. 18, the operation pattern storage unit 212 associates “time”, the inclination angle θx and the inclination angle θy of the “right thigh”, and the inclination angle θx and the inclination angle θy of the “left thigh”. I remember.

In the example illustrated in FIG. 18, for example, when the “time” is “t1”, the inclination angle θx and the inclination angle θy detected by the posture detection unit 100a attached to the “right thigh” are “10”. (Degree) and “0” (degree). When the “time” is “t1”, the inclination angle θx and the inclination angle θy detected by the posture detection unit 100a attached to the “left thigh” are “0” (degrees) and “0”. (Degree).
The motion pattern storage unit 212 may store a plurality of motion patterns such as a walking motion pattern, a running motion pattern, and a golf swing motion pattern.

  Returning to the description of FIG. 16 again, the motion data storage unit 213 stores the motion patterns measured by the posture detection units 100a in an integrated manner. The motion data storage unit 213 stores, for example, time information and the inclination angle θx and the inclination angle θy for each attachment location (attachment portion) in association with each other, for example, in the same manner as the reference pattern of a plurality of portions shown in FIG. .

The terminal control unit 220 is a processor including a CPU, for example, and controls the mobile terminal 200 in an integrated manner. For example, the terminal control unit 220 controls each posture detection unit 100 a via the communication unit 204 based on information stored in the unit information storage unit 211.
For example, the terminal control unit 220 acquires a reference pattern of a plurality of parts of a predetermined operation stored in the operation pattern storage unit 212, and sends the communication unit 204 to the posture detection unit 100a corresponding to each attachment part (each attachment part). And stored in the motion pattern storage unit 123 of the posture detection unit 100a. Further, the terminal control unit 220 transmits reference value information such as various threshold values and reference ranges acquired via the operation unit 201 via the communication unit 204 and stores them in the reference value storage unit 122 of the posture detection unit 100a. Let And the terminal control part 220 transmits via the communication part 204, and makes each attitude | position detection unit 100a start measurement of an attitude | position and an operation | movement.

  Further, the terminal control unit 220 acquires measurement data measured by each posture detection unit 100a through the communication unit 204, and stores the acquired measurement data in the operation data storage unit 213. That is, the terminal control unit 220 associates the acquired time information with the inclination angle θx and the inclination angle θy for each attachment location (attachment site), and stores them in the operation data storage unit 213.

Next, the operation of the posture detection system 1 according to the present embodiment will be described with reference to FIG.
In the example shown in this figure, the posture detection system 1 includes two posture detection units 100a and is an example of a case where the traveling motion of the user U1 is measured. In this figure, posture detection unit 100a-1 is mounted on the right thigh of user U1, and posture detection unit 100a-2 is mounted on the left thigh of user U1.

  The mobile terminal 200 is connected to the attitude detection unit 100a-1 and the attitude detection unit 100a-2 by, for example, wireless communication. The mobile terminal 200 transmits the reference pattern of the traveling motion stored in the motion pattern storage unit 212 to the posture detection unit 100a-1 and the posture detection unit 100a-2, and stores the motion pattern of the posture detection unit 100a as the motion pattern. Stored in the unit 123. That is, the terminal control unit 220 of the mobile terminal 200 transmits the motion pattern corresponding to the “right thigh” among the reference patterns of the travel motion stored in the motion pattern storage unit 212 to the posture detection unit 100a-1. Remember me. In addition, the terminal control unit 220 transmits the motion pattern corresponding to the “left thigh” among the reference patterns of the travel motion stored in the motion pattern storage unit 212 to the posture detection unit 100a-2 for storage.

The portable terminal 200 acquires measurement data from the posture detection unit 100a-1 and the posture detection unit 100a-2 by causing the posture detection unit 100a-1 and the posture detection unit 100a-2 to start measurement, and an operation data storage unit It is stored in 213.
Each of the posture detection unit 100a-1 and the posture detection unit 100a-2 compares the motion pattern based on the tilt angle θx and the tilt angle θy detected by the tilt sensor 110a with the reference pattern stored in the motion pattern storage unit 123. Based on the comparison result, the output unit 113 outputs an alarm. It should be noted that different sound patterns are set for the sound pattern output as an alarm so that the posture detection unit 100a-1 and the posture detection unit 100a-2 can be distinguished. As described above, each of the posture detection unit 100a-1 and the posture detection unit 100a-2 outputs an alarm when, for example, the posture and the motion deviate from the reference pattern of the walking motion.

In the above-described example, the example in which the reference pattern of a plurality of parts corresponding to each operation is stored in the operation pattern storage unit 212 in advance is described. However, the measurement data stored in the operation data storage unit 213 is It may be used as a reference pattern for a plurality of parts.
In the above-described example, the example in which the traveling motion is measured using the two posture detection units 100a has been described. However, the posture detection system 1 can cope with the following cases.

  The posture detection system 1 measures the posture and motion of each part by, for example, mounting the posture detection unit 100a on both knees, both elbows, abdomen, and head of the user U1 in walking motion. In this case, for example, the posture detection system 1 determines a walking action for a diet based on how to swing the knees and elbows, prevents the fall from the inclination of the abdomen (trunk), the rise of the legs (knee), and the like. It is possible to cope with walking determination.

  The posture detection system 1 also measures the posture and motion of each part by, for example, mounting the posture detection unit 100a on both knees, both elbows, abdomen, and head of the user U1 in a running motion. Thus, the traveling form can be determined. In this case, the posture detection system 1 supports, for example, determination of a traveling method for a long distance or a traveling method for a short distance from how to swing an arm, how to raise a leg, and how to tilt an abdomen (trunk). can do.

In addition, the posture detection system 1 similarly applies a posture detection unit 100a to the knees, both elbows, the abdomen, the head, etc. of the user U1 in a baseball batting operation or a pitching operation, It can correspond to the determination of the throwing form.
In addition, for example, in a golf swing operation or a pitching operation, the posture detection system 1 similarly mounts the posture detection unit 100a on both knees, both elbows, an abdomen, a head, etc. of the user U1 to perform the swing operation. It can correspond to the determination.

In addition, for example, in the dance operation, the posture detection system 1 similarly supports the determination of the dance form by mounting the posture detection unit 100a on the knees, both elbows, the abdomen, the head, and the like of the user U1. be able to.
In the example described above, an example in which a plurality of posture detection units 100a are attached to one user U1 has been described. However, one or a plurality of posture detection units 100a are attached to a plurality of users U1. Also good. The posture detection system 1 can determine, for example, whether or not each user U1 is performing the same operation in a group dance.

  Further, in this case, posture detection is performed so that a plurality of users U1 can simultaneously start dancing by transmitting an instruction to start measurement to posture detection unit 100a attached to each user U1. The unit 100a may output an operation start sound. Further, as an external operation related to the start of measurement of the operation, for example, the mobile terminal 200 may output music for dance from the output unit 203. Further, the posture detection unit 100a may perform blinking of light using a light emitting diode or the like as a notification indicating that the user U1 has deviated from the reference pattern to the dance instructor. When measuring an operation pattern such as dance, the measurement control unit 131a may associate the measurement data with the music information and store them in the measurement data storage unit 121.

  In the above-described posture detection system 1 of the present embodiment, an example in which the mobile terminal 200 is provided to link a plurality of posture detection units 100a has been described. However, one posture detection unit 100a is used as a parent device (control device). Instead of the mobile terminal 200, each posture detection unit 100a may be controlled. That is, the posture detection unit 100a may have a function equivalent to that of the mobile terminal 200.

As described above, the posture detection system 1 (information measurement system) according to the present embodiment includes the posture detection unit 100a that can be attached to the user U1 (person to be measured), and the mobile terminal 200 that controls the posture detection unit 100a ( Control device).
Accordingly, the posture detection system 1 can accurately measure the movement information (for example, the posture and movement of the user U1) without being influenced by the inertial force, like the posture detection unit 100a described above. Moreover, since the attitude | position detection system 1 can control the attitude | position detection unit 100a easily from the portable terminal 200, it can improve the convenience.

Further, the posture detection system 1 according to the present embodiment includes a plurality of posture detection units 100a. Each of the plurality of posture detection units 100a is attached to a different part of the user U1 (measurement target person).
Thereby, the posture detection system 1 according to the present embodiment can measure more complicated operations and postures in cooperation with the plurality of posture detection units 100a.

The present invention is not limited to the above embodiments, and can be modified without departing from the spirit of the present invention.
For example, the tilt sensor is not limited to the above-described form, and the following first to fourth modifications may be applied instead of the tilt sensor 110 (110a, 110b).

<First Modification>
FIG. 20 is a block diagram illustrating an inclination sensor 110c according to a first modification.
As shown in FIG. 20, the inclination sensor 110c includes a pressure sensor (11, 12), a moving mechanism 20, a magnet 31, a rotation detection unit 32, a synchronous clock signal generation unit 33, a power supply unit 34, and a slip. The ring 35 and the inclination information detection part 40c are provided. Moreover, the inclination information detection part 40c is provided with the synchronous detection part 41b and the inclination angle production | generation part 42a.
In FIG. 20, the same components as those shown in FIGS. 5 and 11 are denoted by the same reference numerals, and the description thereof is omitted. Further, the pressure sensors (11, 12) have the same configuration as the pressure sensor 10 described above, and will be described as the pressure sensor 10 when an arbitrary pressure sensor included in the inclination sensor 110c is indicated or when not particularly distinguished. .

The inclination sensor 110c of the first modification is an example in the case where a plurality of pressure sensors 10 are provided. The tilt sensor 110c includes, for example, two pressure sensors 10.
The pressure sensor 11 (first pressure sensor) and the pressure sensor 12 (second pressure sensor) are arranged on the rotating plate 21 so that the rotation angles on the rotating shaft C1 are shifted from each other by 90 degrees on the rotating plate 21. ing. Thereby, the pressure sensor 11 and the pressure sensor 12 output a sine wave output signal whose phase is shifted by 90 degrees due to the rotation of the rotating plate 21.

The synchronous detection unit 41 b performs synchronous detection based on the output signal of the pressure sensor 11 and the synchronous clock signal output from the synchronous clock signal generation unit 33. The synchronous detection unit 41b performs synchronous detection based on the output signal of the pressure sensor 12 and the synchronous clock signal output from the synchronous clock signal generation unit 33.
The tilt angle generation unit 42a generates the tilt angle θx and the tilt angle θy by executing the same processing as in the second embodiment on the execution results of the two synchronous detections by the synchronous detection unit 41b.

  In addition, you may make it arrange | position the rotating plate 21 in parallel with a horizontal surface with the inclination sensor 110c of the 1st modification, and the inclination sensor 110a by 2nd Embodiment. In this case, the tilt angle generation unit 42a performs the same processing as the tilt angle generation unit 42 of the first embodiment on the execution results of the two synchronous detections, whereby the tilt angle θx and the tilt angle θy. Is generated. That is, in this case, the inclination sensor 110c (inclination sensor 110a) generates the angle β generated using the above-described equation (1) as the inclination angle θx and the inclination angle θy. When the rotating plate 21 is arranged in parallel with the horizontal plane, the inclination sensor 110c (inclination sensor 110a) determines the inclination polarity (inclination angle sign) from the output signal of the pressure sensor 10. it can.

<Second Modification>
FIG. 21 is a block diagram showing an inclination sensor 110d of the second modification.
As shown in FIG. 21, the inclination sensor 110d includes the pressure sensor 10, the moving mechanism 20a, the magnet 31, the position detection unit 32a, the synchronous clock signal generation unit 33, the power supply unit 34, the flexible substrate 35a, An inclination information detection unit 40d. In addition, the inclination information detection unit 40d includes a synchronous detection unit 41 and an inclination angle generation unit 42b.
In FIG. 21, the same components as those shown in FIG. 5 are denoted by the same reference numerals, and the description thereof is omitted.

In the second modification, an example in which the movement of the pressure sensor 10 is a linear movement that reciprocates linearly instead of a circular movement will be described.
The moving mechanism 20a includes a moving plate 25 (linear moving body) in which the pressure sensor 10 is arranged and can move linearly, and moves the pressure sensor 10 linearly by moving the moving plate 25 linearly. That is, the moving mechanism 20a enables linear movement that causes the pressure sensor 10 to reciprocate linearly. Further, the moving mechanism 20 a includes, for example, a linear tracking mechanism 50, a motor control unit 22, and a motor 23.

The linear tracking mechanism 50 includes a rotating plate 21, a crankshaft 24, a moving plate 25, and a rail 26. The linear tracking mechanism 50 performs a rotational movement of the rotating plate 21 by linear movement of the moving plate 25 (for example, linear movement in the X-axis direction). ).
The crankshaft 24 transmits the rotational movement of the rotating plate 21 to the moving plate 25 and converts it into linear movement (for example, linear movement in the X-axis direction (horizontal)).
The moving plate 25 (an example of a linear moving body) includes the pressure sensor 10 and the magnet 31, and the rotating plate 21 is rotated by the motor 23. Move linearly in the axial direction.

The motor control unit 22 controls the rotational plate 21 to rotate at a predetermined rotational speed so that the pressure sensor 10 moves linearly as described above.
The position detection unit 32a (an example of a movement information detection unit) detects movement information of the pressure sensor 10. The position detection unit 32a is, for example, a magnetic detection element such as a Hall element, and detects the reference position of the moving plate 25 when the magnet 31 disposed on the moving plate 25 approaches, and generates a detection clock as a synchronous clock signal. To the unit 33.

The inclination angle generation unit 42b generates the angle β generated using the synchronous detection execution result by the synchronous detection unit 41 and the above-described equation (1) as the inclination angle θ.
In addition, when generating the inclination angles (inclination angle θx and inclination angle θy) in two directions (biaxial directions) using the second modification, the posture detection unit 100 (100a, 100b) is orthogonal. Two tilt sensors 110d arranged in different directions may be provided.

<Third Modification>
FIG. 22 is a block diagram illustrating an inclination sensor 110e according to a third modification.
As shown in FIG. 22, the inclination sensor 110e includes a pressure sensor 10, a moving mechanism 20a, a magnet 31, a position detection unit (32a-1, 32a-2), a power supply unit 34, a flexible substrate 35a, and an inclination. And an information detection unit 40e.
In FIG. 22, the same components as those shown in FIG. 21 are denoted by the same reference numerals, and the description thereof is omitted.

In the third modified example, an example will be described in which inclination information is detected based on outputs of the pressure sensor 10 at two locations moved linearly instead of synchronous detection based on a periodic output signal of the pressure sensor 10.
The position detectors (32a-1, 32a-2) have the same configuration as the position detector 32a, and detect the moving position of the moving plate 25 when the magnet 31 arranged on the moving plate 25 approaches. A detection signal is output to the inclination information detection unit 40e. In the third modification, the position detectors (32a-1, 32a-2) will be described as the position detector 32a when indicating any position detector included in the inclination sensor 110e, or when not particularly distinguished. .
For example, the position detection unit 32a-1 detects that the pressure sensor 10 has moved to the first position, and outputs a detection signal to the inclination information detection unit 40e at the first position. For example, the position detection unit 32a-2 detects that the pressure sensor 10 has moved to the second position, and outputs a detection signal to the inclination information detection unit 40e at the second position. It is assumed that the first position and the second position are separated by a moving distance ΔD of the pressure sensor 10 that moves parallel to the rail 26.

  The inclination information detection unit 40e detects the inclination information of the detection target based on the movement distance of the pressure sensor 10 and the change in the output value of the pressure sensor 10 with respect to the movement distance. For example, the inclination information detection unit 40e is based on the movement distance ΔD between the first position and the second position described above and the change in the output value of the pressure sensor 10 with respect to the movement distance ΔD. Detect the tilt angle of the direction. In addition, the inclination information detection unit 40e includes an inclination angle generation unit 42c.

  The inclination angle generation unit 42c acquires the output value (voltage V3) of the pressure sensor 10 at the first position where the detection signal is output by the position detection unit 32a-1. Further, the inclination angle generation unit 42c acquires the output value (voltage V4) of the pressure sensor 10 at the second position where the detection signal is output by the position detection unit 32a-2. The inclination angle generator 42b calculates a change amount ΔVo (= V4−V3) between the output value at the first position and the output value at the second position. Then, the inclination angle generation unit 42b calculates the angle β as the inclination angle θ based on the movement distance ΔD and the change amount ΔVo using the above-described equation (1). In the third modified example, in the equation (1), the above-described movement distance ΔD is used instead of the movement distance (2 × Rs).

As described above, in the third modification, the inclination information detection unit 40e includes the movement distance (for example, movement distance ΔD) of the pressure sensor 10 and the change (for example, the change amount ΔVo) of the output value of the pressure sensor 10 with respect to the movement distance. ) To detect inclination information (for example, inclination angle θ) of the detection object.
Thereby, the inclination sensor 110e according to the third modification can detect inclination information with a simple configuration as compared with the case where the above-described synchronous detection is used.

<Fourth Modification>
FIG. 23 is a block diagram illustrating an inclination sensor 110f according to a fourth modification.
As shown in FIG. 23, the inclination sensor 110f includes the pressure sensor 10, the moving plate 25, the rail 26, the magnet 31, and the position detectors (32a-1, 32a-2, ..., 32a-N). And a power supply unit 34, a flexible substrate 35a, and an inclination information detection unit 40f.
In FIG. 23, the same components as those shown in FIG. 22 are denoted by the same reference numerals, and the description thereof is omitted.

  In the fourth modified example, another example in the case of detecting inclination information based on the output of the pressure sensor 10 at two locations moved linearly will be described. In the third embodiment, the third modification is that the moving mechanism 20a is not provided, the moving plate 25 and the rail 26 without the motor 23 and the like are provided, and the pressure sensor 10 is linearly moved by an external force or acceleration. And different.

  In the fourth modified example, the moving plate 25 includes the pressure sensor 10 and the magnet 31, and is configured to freely move linearly on the rail 26 (linear tracking). The moving plate 25 moves on the rail 26 by, for example, an external force applied to the detection target (for example, an acceleration component in the measurement axis direction (X-axis direction)) or human power.

The position detection units (32a-1, 32a-2,..., 32a-N) have the same configuration as the position detection unit 32a, and the moving plate 25 approaches the moving plate 25 when the moving plate 25 approaches. 25 movement positions are detected, and a detection signal is output to the inclination information detection unit 40f. In the present embodiment, the position detection unit (32a-1, 32a-2, ..., 32a-N) indicates an arbitrary position detection unit included in the inclination sensor 110f or is not particularly distinguished. The detection unit 32a will be described.
In addition, the positional relationship of a position detection part (32a-1, 32a-2, ..., 32a-N) shall be predetermined. For example, the position detection units (32a-1, 32a-2,..., 32a-N) are arranged at predetermined position intervals, and the position detection units (32a-1, 32a-2,..., 32a-) are arranged. The movement distance of the pressure sensor 10 can be detected by the output of N).

  The inclination information detection unit 40f detects the inclination information of the detection object based on the movement distance of the pressure sensor 10 and the change in the output value of the pressure sensor 10 with respect to the movement distance. The inclination information detection unit 40f is, for example, a detection target based on the movement distance ΔD obtained by the output of two of the plurality of position detection units 32a and the change in the output value of the pressure sensor 10 with respect to the movement distance ΔD. The inclination angle of the object in the X-axis direction is detected. In addition, the inclination information detection unit 40f includes an inclination angle generation unit 42d.

  The inclination angle generation unit 42d outputs the output value of the pressure sensor 10 at the first position where the detection signal is output by two of the position detection units (32a-1, 32a-2, ..., 32a-N). (Voltage V3) and the output value (voltage V4) of the pressure sensor 10 at the second position are acquired. The inclination angle generator 42d calculates a change amount ΔVo (= V4−V3) between the output value at the first position and the output value at the second position. Then, the inclination angle generation unit 42d calculates the inclination angle θ based on the movement distance ΔD and the change amount ΔVo using the above-described equation (1). In the fourth modification, the above-described movement distance ΔD is used in the formula (1) instead of the movement distance (2 × Rs).

  Note that the tilt angle generation unit 42d, for example, when the detection signal that detects the magnet 31 is output from the three or more position detection units 32a within a predetermined period, for example, the three or more position detection units 32a. Two of them that are the farthest away may be selected, and the distance between the two position detectors 32a may be set as the movement distance ΔD. In this case, the inclination angle generation unit 42d, for example, the amount of change ΔVo at the position of the two position detection units 32a that have detected the magnet 31 with the greatest distance, and the distance (movement distance ΔD) between the two position detection units 32a. Based on the above, the inclination angle θ is calculated.

As described above, the inclination sensor 110f according to the fourth modified example does not include the moving mechanism 20a as in the third modified example, but includes the moving plate 25 and the rail 26, and the pressure sensor 10 is adjusted by an external force or acceleration. Move straight. Then, the inclination information detection unit 40f detects the detection target based on the movement distance (for example, movement distance ΔD) of the pressure sensor 10 and the change in the output value of the pressure sensor 10 with respect to the movement distance (for example, the change amount ΔVo). Inclination information (for example, inclination angle θ) is detected.
Thereby, the inclination sensor 110f according to the fourth modification can detect inclination information with a simple configuration as compared with the case where the above-described synchronous detection is used.

In each of the above-described embodiments and modifications, the inclination sensor 110 (110a to 110f) has been described as moving the pressure sensor 10 in a circular shape or a linear shape. Other movements may be used.
Further, in each of the embodiments and the modifications described above, the example in which the pressure sensor 10 is a differential pressure sensor has been described. However, for example, another type of pressure sensor such as an absolute pressure sensor may be used.

  Further, in each of the above-described embodiments and modifications, the example in which the Hall element is used as the movement information detection unit (the rotation detection unit 32, the position detection unit 32a) has been described. Instead of the Hall element, for example, a microswitch An encoder, an optical sensor, or the like may be used. Further, the rotating plate 21 or the moving plate 25 may include a movement information detection unit such as a Hall element, and the magnet 31 may be disposed on the moving path of the rotating plate 21 or the moving plate 25.

Further, in each of the above-described embodiments and the first modification, an example in which the slip ring 35 is used as a signal transmission unit that transmits an output signal output from the pressure sensor 10 to the inclination information detection unit 40 (40a to 40c). As described above, instead of the slip ring 35, other means such as optical transmission using a rotary connector, wireless communication, a photocoupler, or the like may be used. Further, as means for supplying the power supply voltage (power supply power) to the pressure sensor 10, instead of the slip ring 35, means such as a rotary connector, wireless power feeding, and a battery provided in the rotating plate 21 may be used.
Also in the second to fourth modifications, the above-described means for supplying power supply voltage (power supply power) and signal transmission means may be used instead of the flexible substrate 35a.

  Moreover, although each said embodiment demonstrated the example implemented independently, you may implement combining some or all of several embodiment. For example, the posture detection unit 100 of the first embodiment may be applied to the fourth embodiment, and the correction process of the third embodiment may be applied to the second embodiment.

Further, in each of the above-described embodiments, the inclination information detection unit 40 (40a to 40d) has described an example in which the amount of change in the output signal of the pressure sensor 10 is detected using synchronous detection. It is not something. The inclination information detection unit 40 (40a to 40d) may use, for example, a rectifier circuit or a peak hold circuit, or may detect the amount of change in the output signal of the pressure sensor 10 based on the difference before and after the movement. Good.
Further, in each of the embodiments described above, the example in which the alarm is output to the output unit 113 has been described, but the alarm may be output to the display unit 112.

  Moreover, in each said embodiment, although the inclination sensor 110 (110a-110f) demonstrated the example provided with the inclination information detection part 40 (40a-40f), the control part 130 with which the attitude | position detection unit 100 (100a, 100b) is provided. (130a, 130b) may be provided with the function of the inclination information detection unit 40 (40a to 40f).

  In the third embodiment, the example in which the temperature sensor 115, the absolute pressure sensor 116, and the correction information storage unit 124 are provided outside the inclination sensor 110b has been described. However, the inclination sensor 110b includes the temperature sensor 115, A part or all of the absolute pressure sensor 116 and the correction information storage unit 124 may be provided. Moreover, although the inclination sensor 110b demonstrated the example provided with both the temperature correction | amendment part 43 and the atmospheric pressure correction | amendment part 44, you may make it provide either one. Moreover, although the temperature correction part 43 and the atmospheric pressure correction part 44 demonstrated the example which correct | amends the execution result of the synchronous detection part 41, you may make it correct | amend the output signal of the pressure sensor 10. FIG. Moreover, although the temperature correction part 43 and the atmospheric pressure correction part 44 demonstrated the example corrected based on a correction coefficient and an offset value, it is not limited to this, Based on any one of a correction coefficient and an offset value Or may be corrected by another method.

Moreover, in said 4th Embodiment, although the example which uses portable terminals 200, such as a smart phone, was demonstrated as an example of a control apparatus, it is not limited to this, A control apparatus is a PDA (Personal Digital Assistant). Or a personal computer (PC).
In the posture detection system 1, the example in which each posture detection unit 100 a determines whether to output an alarm and each posture detection unit 100 a outputs an alarm has been described. However, the present invention is not limited to this. For example, the mobile terminal 200 may determine whether to output an alarm and instruct each posture detection unit 100a to output the alarm, or the mobile terminal 200 may output an alarm. It may be.

  In each of the above embodiments, the moving mechanism 20 (20a) includes the motor 23 and actively moves the pressure sensor 10. However, the present invention is not limited to this. For example, the inclination sensor 110 (110a to 110e) does not include the moving mechanism 20 (20a) as in the fourth modification, and the pressure sensor 10 is passively moved by a windmill or human power. May be.

In addition, each structure with which the attitude | position detection system 1 mentioned above and the attitude | position detection unit 100 (100a, 100b) are provided has a computer system inside. And the program for implement | achieving the function of each structure with which the attitude | position detection system 1 and attitude | position detection unit 100 (100a, 100b) mentioned above are equipped is recorded on a computer-readable recording medium, and the program recorded on this recording medium To the computer system, and the processing in each configuration included in the posture detection system 1 and the posture detection unit 100 (100a, 100b) described above may be performed. Here, “loading and executing a program recorded on a recording medium into a computer system” includes installing the program in the computer system. The “computer system” here includes an OS and hardware such as peripheral devices.
Further, the “computer system” may include a plurality of computer devices connected via a network including a communication line such as the Internet, WAN, LAN, and dedicated line. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. As described above, the recording medium storing the program may be a non-transitory recording medium such as a CD-ROM.

  The recording medium also includes a recording medium provided inside or outside that is accessible from the distribution server in order to distribute the program. Note that the program is divided into a plurality of parts and downloaded at different timings, and then each of the constituents included in the posture detection system 1 and the posture detection unit 100 (100a, 100b) and the divided programs are distributed. The distribution server may be different. Furthermore, the “computer-readable recording medium” holds a program for a certain period of time, such as a volatile memory (RAM) inside a computer system that becomes a server or a client when the program is transmitted via a network. Including things. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, and what is called a difference file (difference program) may be sufficient.

Moreover, you may implement | achieve part or all of the function with which the attitude | position detection unit 100 (100a, 100b) mentioned above is integrated circuits, such as LSI (Large Scale Integration). Each function described above may be individually made into a processor, or a part or all of them may be integrated into a processor. Further, the method of circuit integration is not limited to LSI, and may be realized by a dedicated circuit or a general-purpose processor. In addition, when an integrated circuit technology that replaces LSI appears due to the advancement of semiconductor technology, an integrated circuit based on the technology may be used.
In addition, some or all of the functions of the tilt information detection unit 40 (40a to 40e) described above are realized as a simple circuit using discrete components (for example, single function components, single elements, etc.) such as a comparator. Also good.

DESCRIPTION OF SYMBOLS 1 Posture detection system 10, 11, 12 Pressure sensor 20, 20a Moving mechanism 21 Rotating plate 22 Motor control part 23 Motor 24 Crankshaft 25 Moving plate 26 Rail 31 Magnet 32 Rotation detecting part 32a, 32a-1, 32a-2, 32a -N Position detection unit 33, 33a Synchronous clock signal generation unit 34 Power supply unit 35 Slip ring 35a Flexible substrate 40, 40a, 40b, 40c, 40d, 40e, 40f Inclination information detection unit 41, 41a, 41b Synchronous detection unit 42, 42a , 42b, 42c, 42d Inclination angle generator 43 Temperature correction unit 44 Atmospheric pressure correction unit 50 Linear tracking mechanism 100, 100a, 100a-1, 100a-2, 100b Attitude detection unit 110, 110a, 110b, 110c, 110d, 110e Tilt sensor 11, 201 Operation unit 112, 202 Display unit 113, 203 Output unit 114, 204 Communication unit 115 Temperature sensor 116 Absolute pressure sensor 120, 120a, 120b Storage unit 121 Measurement data storage unit 122 Reference value storage unit 123, 212 Operation pattern storage Unit 124 correction information storage unit 130, 130a, 130b control unit 131, 131a, 131b measurement control unit 200 portable terminal 210 terminal storage unit 211 unit information storage unit 213 operation data storage unit 220 terminal control unit BD abdomen BT belt C1 rotating shaft U1 User

Claims (16)

A tilt sensor for detecting tilt information of the device itself;
A measurement control unit that measures motion information related to the motion of the measurement subject based on the tilt information detected by the tilt sensor, and
The tilt sensor is
A pressure sensor that is arranged so as to be movable relative to its own device and detects the pressure of the fluid;
An information measurement apparatus comprising: an inclination information detection unit that detects the inclination information based on an output of the pressure sensor and movement information of the pressure sensor. The tilt sensor is
A movement mechanism for moving the pressure sensor along a predetermined movement path with respect to the device itself,
The inclination information detection unit detects the inclination information based on movement information of the pressure sensor moved along the predetermined movement path by the movement mechanism and an output of the pressure sensor. Item 2. The information measuring device according to Item 1. The moving mechanism is
Comprising a rotating body on which the pressure sensor is disposed, moving the pressure sensor in a circular shape by rotating the rotating body;
The inclination information detection unit
Synchronous detection is performed based on a periodic output signal that is moved along the predetermined movement path and output from the pressure sensor, and a reference signal based on the movement information, and based on a result of the synchronous detection, The information measuring device according to claim 2, wherein inclination information is detected. The inclination information includes inclination information in a first direction and inclination information in a second direction orthogonal to the first direction,
The inclination information detection unit
Performing synchronous detection based on the periodic output signal and a first reference signal based on the movement information, and detecting tilt information in the first direction based on a result of the synchronous detection; Synchronous detection is performed based on the periodic output signal and the second reference signal that is 90 degrees out of phase with the first reference signal, and the second direction is determined based on the result of the synchronous detection. The information measurement apparatus according to claim 3, wherein the inclination information is detected. The measurement control unit determines whether or not the tilt information detected by the tilt information detection unit is within a predetermined reference range, and outputs a notification regarding the operation information to the output unit based on the determination result The information measuring device according to any one of claims 1 to 4, wherein the information measuring device is used. The measurement control unit, when the inclination information is equal to a first threshold value, causes the output unit to output an alarm indicating that the inclination information has reached the first threshold value as a notification regarding the operation information. The information measuring device according to claim 5. The measurement control unit outputs an alarm indicating that the tilt information has become equal to or greater than the second threshold to the output unit as a notification regarding the operation information when the tilt information is equal to or greater than the second threshold. The information measuring device according to claim 5 or 6, wherein: The measurement control unit outputs, to the output unit, an alarm indicating that the tilt information is equal to or lower than the third threshold value as a notification regarding the operation information when the tilt information is equal to or lower than a third threshold value. The information measuring device according to any one of claims 5 to 7, wherein the information measuring device is used. The measurement control unit outputs an alarm indicating that the tilt information is out of the predetermined reference range to the output unit as a notification regarding the operation information when the tilt information is not within the predetermined reference range. The information measuring device according to any one of claims 5 to 8, wherein the information measuring device is used. The measurement control unit, when the tilt information is within the predetermined reference range, outputs an alarm indicating that the tilt information is within the predetermined reference range to the output unit as a notification regarding the operation information. The information measuring apparatus according to claim 5, wherein the information measuring apparatus outputs the information. The measurement control unit compares an operation pattern indicating a change of the tilt information with respect to time with a reference pattern serving as a reference of the predetermined operation pattern, and notifies the operation information based on the comparison result. The information measuring device according to any one of claims 5 to 10, wherein the information is output to an output unit. A temperature sensor for detecting the temperature;
The information measuring device according to any one of claims 1 to 11, further comprising: a temperature correction unit that corrects the inclination information based on the temperature detected by the temperature sensor. An absolute pressure sensor that detects atmospheric pressure;
The information measurement device according to claim 1, further comprising: an atmospheric pressure correction unit that corrects the inclination information based on the atmospheric pressure detected by the absolute pressure sensor. . The information measurement according to any one of claims 1 to 13, wherein the motion information includes information indicating an attitude or motion of the measurement target person wearing the device. apparatus. The information measuring device according to any one of claims 1 to 14, wherein the information measuring device is attachable to a measurement subject,
An information measurement system comprising: a control device that controls the information measurement device. A plurality of the information measuring devices;
The information measurement system according to claim 15, wherein each of the plurality of information measurement devices is attached to a different part of the measurement subject.

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