JPWO2015170703A1 - Motion detection program, object motion detection apparatus and method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a motion detection program and an object motion detection device capable of detecting a motion of an object by a simple method other than image processing. A moving distance L (s) is calculated based on an acceleration a (s) of a sensor module 11_s. Further, the direction of movement of the sensor module 11_s is calculated. Communication strength RSSI (s) 2 between the position (x1 (s), y1 (s)) of the sensor module 11_s at the start timing t1 of the predetermined period and the sensor module 11_s at the end timing t2 of the predetermined period, and the distance L Based on (s) and the direction of movement, the position (x2 (s), y2 (s)) of the sensor module 11_s at the end timing t2 of the predetermined period is calculated. [Selection] Figure 6

Description

  The present invention relates to a motion detection program used for detecting a motion of an object based on a detection signal of a sensor module provided in a part where the object moves, such as a wrist of a human body, an object motion, and the like. The present invention relates to a detection apparatus and a method thereof.

  For example, in sports such as golf, a player's form may be imaged with a camera, and the form may be analyzed using the image to help improve the form.

However, in the method using the conventional camera described above, it is necessary to install a camera, and there is a problem that it is difficult for the player to easily check his / her form during play.
Moreover, image processing is necessary to analyze an image acquired by a camera, and there is a problem that accurate image processing is difficult depending on clothes and the like, and accurate analysis cannot be performed.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a motion detection program, an object motion detection device, and a method thereof that can detect the motion of an object by a simple method other than image processing. The purpose is to provide.

  A first aspect of the present invention relates to a motion detection program executed by a processing circuit of a communication device that receives a sensor detection result of a motion of a part from a sensor module provided in the part where the object moves. It is. The motion detection program acquires a first procedure for acquiring a sensor detection result within a predetermined period of the sensor module and a communication strength between the sensor module and the communication device at an end timing of the predetermined period. Based on the second procedure, the sensor detection result acquired in the first procedure, a third procedure for calculating a first distance that the sensor module has moved within the predetermined period, and the first procedure Based on the sensor detection result acquired in the procedure, a fourth procedure for calculating the direction of the movement of the sensor module, a first position of the sensor module at the start timing of the predetermined period, and the second Based on the communication strength acquired in the procedure, the first distance calculated in the third procedure, and the direction of movement calculated in the fourth procedure, the predetermined period of time And a fifth step of calculating a second position of the sensor module in the completion timing is executed by the processing circuit of the communication device.

  According to this configuration, the second position at the end timing of the sensor module is calculated based on the communication strength between the sensor module and the communication device at the end timing of the predetermined period. Here, the position analysis based on the communication strength is more accurate than the position analysis of the sensor alone. Therefore, the second position is calculated with high accuracy. In addition, since it is not necessary to install a camera or the like in detecting the movement of the object, the work load is small and it can be used easily. Furthermore, stable and highly accurate detection is possible without being influenced by the appearance of the object.

Preferably, the motion detection program according to the first aspect of the present invention is configured so that, when the communication device receives the sensor detection result from the plurality of sensor modules, the sensor module for each of the plurality of sensor modules. Using the sensor detection result received from the sensor module and the communication strength with the sensor module, the processing circuit executes the processing of the first to fifth procedures to calculate the second position, The method further includes a sixth procedure for identifying the movement of the object based on the second positions calculated for the plurality of sensor modules.
According to this configuration, the positions of the plurality of sensor modules at the end timing of the predetermined period are calculated based on the sensor detection results from the plurality of sensor modules, and the part of the target object to which the plurality of sensor modules are attached The movement trajectory is identified.

  Preferably, the motion detection program according to the first aspect of the present invention is based on the communication strength acquired in the second procedure, and the first and second communication between the sensor module and the communication device at the end timing of the predetermined period. A seventh procedure for calculating the distance of 2 may be further included. In the fifth procedure, the distance from the first position is a virtual circle or virtual sphere centered on the third position, which is the position of the communication device, and having the radius of the second distance. Identify two points or circles to be the first distance, and identify the point corresponding to the direction of movement calculated in the fourth procedure as the second position among the identified two points or circles Good.

  According to this configuration, based on the communication strength acquired in the second procedure, the second distance between the sensor module and the communication device at the end timing of the predetermined period is based on accuracy with high communication strength. Is calculated with high accuracy. Therefore, the calculation of the second position using the second distance is performed with high accuracy.

Preferably, the sensor detection result may be an acceleration detected by the sensor module.
Preferably, the sensor detection result may further include an angular velocity detected by the sensor module. In this case, in the fifth procedure, the second position may be calculated by further using the angular velocity.

  According to this configuration, by using the acceleration and angular velocity of the sensor module, highly accurate processing in consideration of the attitude of the sensor module is performed.

  Preferably, in the fifth procedure, the virtual circle is elliptically corrected based on the acceleration and the angular velocity indicated by the sensor detection result, and the first position on the virtual ellipse obtained by the correction is corrected. The two points or the circle whose distance is the first distance may be specified.

  According to this configuration, even when direction dependence occurs in the communication strength between the sensor module and the communication device, it can be corrected and highly accurate position detection is possible.

  An object motion detection apparatus according to a second aspect of the present invention includes a sensor module provided in a part where the object moves, and a communication apparatus that receives a sensor detection result of the part movement from the sensor module. The communication device acquires the sensor detection result within a predetermined period from the sensor module, acquires the communication strength between the sensor module and the communication device at the end timing of the predetermined period, and A first distance that the sensor module has moved within the predetermined period is calculated based on the acquired sensor detection result, and a direction of the movement of the sensor module is calculated based on the acquired sensor detection result. And the first position of the sensor module at the start timing of the predetermined period, the acquired communication strength, and the calculated first The distance, based on the orientation of the movement the calculated, to calculate a second position of the sensor module at the end timing of the predetermined period.

  According to this configuration, the second position at the end timing of the sensor module is calculated based on the communication strength between the sensor module and the communication device at the end timing of the predetermined period. Here, the position analysis based on the communication strength is more accurate than the position analysis of the sensor alone. Therefore, the second position is calculated with high accuracy. In addition, since it is not necessary to install a camera or the like in detecting the movement of the object, the work load is small and it can be used easily. Furthermore, stable and highly accurate detection is possible without being influenced by the appearance of the object.

  According to a third aspect of the present invention, there is provided an object motion detection using a sensor module provided in a region where the object moves and a communication device that receives a sensor detection result detected by the sensor module from the sensor module. It is about the method. The object motion detection method includes a first step of transmitting a sensor detection result of the sensor module within a predetermined period from the sensor module to the communication apparatus, and the sensor module and the communication apparatus at an end timing of the predetermined period. The first distance that the sensor module has moved within the predetermined period based on the second step in which the communication device acquires the communication strength between the first and second steps, and the sensor detection result acquired in the first step. A third step in which the communication device calculates, and a fourth step in which the communication device calculates the direction of movement of the sensor module based on the sensor detection result acquired in the first step; The first position of the sensor module at the start timing of the predetermined period, the communication strength acquired in the second step, and the value calculated in the third step A fifth step in which the communication device calculates a second position of the sensor module at the end timing of the predetermined period based on the first distance and the direction of movement calculated in the fourth step; Have

  According to this configuration, the second position at the end timing of the sensor module is calculated based on the communication strength between the sensor module and the communication device at the end timing of the predetermined period. Here, the position analysis based on the communication strength is more accurate than the position analysis of the sensor alone. Therefore, the second position is calculated with high accuracy. In addition, since it is not necessary to install a camera or the like in detecting the movement of the object, the work load is small and it can be used easily. Furthermore, stable and highly accurate detection is possible without being influenced by the appearance of the object.

  ADVANTAGE OF THE INVENTION According to this invention, the program for a motion detection which can detect the motion of a target object by simple methods other than image processing, a target object motion detection apparatus, and its method can be provided.

FIG. 1 is a diagram for explaining an object motion detection apparatus according to an embodiment of the present invention. FIG. 2 is a diagram for explaining communication between the sensor module shown in FIG. 1 and the portable terminal device. FIG. 3 is a functional block diagram of the sensor module shown in FIG. FIG. 4 is a functional block diagram of the portable terminal device shown in FIG. FIG. 5 is a diagram for explaining position calculation processing by the object motion detection apparatus shown in FIG. 1. FIG. 6 is a diagram for explaining position calculation processing by the object motion detection apparatus shown in FIG. 7A and 7B are diagrams for explaining the initialization process of the object motion detection apparatus. FIG. 8 is a flowchart for explaining an operation example of the object motion detection apparatus shown in FIG.

FIG. 1 is a diagram for explaining an object motion detection apparatus 1 according to an embodiment of the present invention.
The object motion detection device 1 shown in the example of FIG. 1 detects the motion in each part of the user's body in order to analyze the user's golf swing.
As illustrated in FIG. 1, the object motion detection device 1 includes sensor modules 11_1, 11_2, and 11_3 and a portable terminal device 15.
The object motion detection device 1 is an example of the object motion detection device of the present invention, the sensor modules 11_1, 11_2, and 11_3 are examples of the sensor module of the present invention, and the portable terminal device 15 is the communication device of the present invention. It is an example.

The sensor module 11_1 is fixed to the user's glasses 21. The sensor module 11_2 is fixed to the golf club 22 used by the user. The sensor module 11_3 is fixed to the wrist 23 of the user. The portable terminal device 15 is fixed to a user's belt 25.
When the user swings the golf club 22, the glasses 21, the golf club 22, and the wrist 23 move according to the swing, and the movement locus is calculated by the portable terminal device 15.

FIG. 2 is a diagram for explaining communication between the sensor modules 11_1, 11_2, and 11_3 and the portable terminal device 15.
As shown in FIG. 2, the sensor modules 11_1, 11_2, and 11_3 and the portable terminal device 15 perform wireless communication. The communication strength depends on the distance between the sensor modules 11_1, 11_2, and 11_3 and the portable terminal device 15.
In addition, the acceleration and angular velocity detected by the sensor modules 11_1, 11_2, and 11_3 are transmitted from the sensor modules 11_1, 11_2, and 11_3 to the portable terminal device 15.

FIG. 3 is a functional block diagram of the sensor module 11_s (s = 1, 2, 3) shown in FIG.
As illustrated in FIG. 3, the sensor module 11_s includes, for example, an acceleration sensor 31_s, an angular velocity sensor 33_s, and a communication unit 35_s.
The acceleration sensor 31_s detects acceleration (sensor coordinate system) for each of the x, y, and z axes, and outputs an acceleration signal S31_s indicating the detected acceleration to the communication unit 35_s.
The angular velocity sensor 33_s detects an angle at which the sensor module 11_s rotates with respect to the reference axis in one second, and outputs an angular velocity signal S33_s indicating the detected angle to the communication unit 35_s.

  The communication unit 35_s transmits the acceleration signal S31_s input from the acceleration sensor 31_s and the angular velocity signal S33_s input from the angular velocity sensor 33_s to the portable terminal device 15 by wireless communication. As the wireless communication, for example, Bluetooth (trademark) or the like is used.

FIG. 4 is a functional block diagram of the portable terminal device 15 shown in FIG.
As shown in FIG. 4, the portable terminal device 15 includes, for example, a communication unit 41, an operation unit 43, a display 45, an acceleration sensor 47, an angular velocity sensor 49, a memory 51, a processing circuit 53, and the like. The portable terminal device 15 is, for example, a smartphone owned by the user.

The communication unit 41 performs wireless communication with the sensor modules 11_1, 11_2, and 11_3.
The operation unit 43 is an operation unit such as a keyboard, a mouse, and a touch panel, and outputs an operation signal corresponding to a user operation to the processing circuit 53.
The display 45 displays the processing result of the processing circuit 53 and the like.

The acceleration sensor 47 detects acceleration (sensor coordinate system) for each of the x, y, and z axes, and outputs an acceleration signal indicating the detected acceleration to the processing circuit 53.
The angular velocity sensor 49 detects an angle at which the portable terminal device 15 is rotated per second with respect to the reference axis, and outputs an angular velocity signal indicating the detected angle to the processing circuit 53.
The memory 51 stores a motion detection program PRG executed by the processing circuit 53, data used for processing of the processing circuit 53, and processing result data. Here, the motion detection program PRG is an example of the motion detection program of the present invention.
The processing circuit 53 executes the motion detection program PRG and performs the operation of the portable terminal device 15 described in the present embodiment.

Hereinafter, the position detection principle of the sensor module 11_s by the object motion detection device 1 will be described.
Between the distance r (s) between the sensor module 11_s (s = 1, 2, 3) and the portable terminal device 15 and the communication strength RSSI (s) between them, the following equation (1) There is a relationship.
In the following formula (1), “A” and “B” are predetermined constants.

[Equation 1]
RSSI (s) = A-10Blog ₁₀ (r (s)) (1)

The processing circuit 53 of the portable terminal device 15 executes the motion detection program PRG and performs the following processing.
The processing circuit 53 calculates the distance r (s) between the sensor module 11_s and the communication module RSSI (x) of the wireless communication between the above equation (1) and the sensor module 11_s.
The calculated distance r (s) indicates a radius r (s) on a virtual circle or a virtual sphere centered on the portable terminal device 15. As shown in FIG. 5, it can be seen that the sensor module 11 — s is located on a virtual circle or virtual sphere having a radius r (s) with the portable terminal device 15 as the center.

As illustrated in FIG. 6, the processing circuit 53 uses the movement distance L (s) based on the acceleration a (s) indicated by the acceleration signal S35_s received from the sensor module 11_s when the sensor module 11_s moves within a predetermined period. ) Is calculated using the following formula (2). In the following formula (2), t is time and is counted by the timer of the portable terminal device 15. V0 is the speed of the sensor module 11_s at the start timing t1 within the predetermined period. Here, the movement distance L (s) is an example of the first distance of the present invention.
In FIG. 6, the position (x1 (s), y1 (s)) is the position of the sensor module 11_s at the start timing t1 of the predetermined period. The position (x2 (s), y2 (s)) is the position of the sensor module 11_s at the end timing t2 of the predetermined period.
The predetermined period is constant, and the predetermined period is defined continuously in time.

[Equation 2]
L (s) = V0 × t + 1/2 × a (s) × t ² (2)

The processing circuit 53 calculates the direction of movement of the sensor module 11_s based on the acceleration a (s) indicated by the acceleration signal S31_s received from the sensor module 11_s. The direction is calculated, for example, as a direction based on the direction of gravity.
The processing circuit 53 determines the communication strength RSSI between the position (x1 (s), y1 (s)) of the sensor module 11_s at the start timing t1 of the predetermined period and the sensor module 11_s at the end timing t2 of the predetermined period. s) 2, the calculated distance L (s), and the calculated direction of movement of the sensor module 11_s, the position (x2 (s), y2) of the sensor module 11_s at the end timing t2 of the predetermined period (S)) is calculated.

At this time, the position (x1 (s), y1 (s)) at the start timing t1 of the predetermined period is the value of the position (x2 (s), y2 (s)) calculated last time for the previous predetermined period. Is used.
In the position calculation process in the processing circuit 53, a coordinate system having the position of the processing circuit 53 as the origin (0, 0) is used. Here, the origin (0, 0) is an example of the third position of the present invention, and the positions (x1 (s), y1 (s)) are an example of the first position of the present invention. The position (x2 (s), y2 (s)) is an example of the second position of the present invention.

That is, based on the communication strength RSSI (s) 2 between the sensor module 11_s and the portable terminal device 15 at the end timing t2, the processing circuit 53 determines between the sensor module 11_s and the portable terminal device 15 at the end timing t2. The distance r (s) 2 is calculated.
The processing circuit 53 has a position (x1 (s)) at the start timing t1 of the sensor module 11_s on a virtual circle 63 or a virtual sphere centered on the position of the portable terminal device 15 and having a distance r (s) 2 as a radius. , Y1 (s)), two points 65, 67 or a circle having a distance L (s) are specified, and the two points or circles specified are specified based on the acceleration a (s) indicated by the acceleration signal S31_s. The point corresponding to the direction to be detected is specified as the position (x2 (s), y2 (s)) at the end timing t2 of the sensor module 11_s. In the example illustrated in FIG. 6, the point 65 on the virtual circle 63 is specified as the position (x2 (s), y2 (s)).

  Thus, in the present embodiment, the end of the sensor module 11_s is performed using the distance r (s) 2 generated based on the communication strength RSSI (s) 2 with the sensor module 11_s at the end timing t2 of the predetermined period. The position (x2 (s), y2 (s)) at timing t2 is calculated. Here, the analysis based on the communication strength RSSI (s) 2 has higher accuracy than the position analysis of the sensor alone. Therefore, the position (x2 (s), y2 (s)) can be calculated with high accuracy.

  Then, the processing circuit 53 determines the position (x1 (s), y1 (s)) at the start timing t1 of the sensor module 11_s, the position (x2 (s), y2 (s)) at the end timing t2, and the acceleration a (s ), The movement of the user's glasses 21, golf club 22, and wrist 23 is specified.

  The processing circuit 53 uses the acceleration signal S31_s and the angular velocity signal S33_s from the sensor module 11_s when the direction dependency (for example, circle to ellipse) occurs in the sensitivity of the communication strength RSSI (s) with the sensor module 11_s. In addition, after specifying the posture of the sensor module 11_s and performing ellipse correction with intensity, the above calculation is performed using the ellipse as the circle.

7A and 7B are diagrams for explaining the initialization process of the object motion detection device 1. FIG.
In the object motion detection device 1, after the sensor module 11_s is fixed to each part of the user, the sensor module 11_s is arranged in a straight line as shown in FIGS. 7A and 7B, and initialization processing is performed. At this time, the communication module 35_s of the portable terminal device 15 performs position initialization based on the communication strength RSSI (s) with the sensor module 11_s.

Hereinafter, an operation example of the object motion detection apparatus 1 will be described.
FIG. 8 is a flowchart for explaining an operation example of the object motion detection apparatus 1.
The processing of the portable terminal device 15 shown below is realized by the processing circuit 53 shown in FIG. 4 executing the motion detection program PRG.
Step ST1:
As shown in FIG. 1, after the sensor module 11_s is fixed to each part of the user, the sensor module 11_s is arranged in a straight line as shown in FIG. 7, and initialization processing is performed. At this time, the communication module 35_s of the portable terminal device 15 performs position initialization based on the communication strength RSSI (s) with the sensor module 11_s.

Next, the portable terminal device 15 performs the following steps ST2 to ST8 for each of the sensor modules 11_s while the user is playing.
Step ST2:
The portable terminal device 15 receives the acceleration signal S31_s from the sensor module 11_s, and stores the acceleration a (s) of the sensor module 11_s within a predetermined period in the memory 51 shown in FIG.

Step ST3:
The portable terminal device 15 stores the communication strength RSSI (s) with the sensor module 11_s at the end timing t2 of the predetermined period in the memory 51.

Step ST4:
The processing circuit 53 reads the communication strength RSSI (s) from the memory 51, and calculates the distance r (s) between the sensor module 11_s and the portable terminal device 15 based on the above equation (1).

Step ST5:
The processing circuit 53 reads the acceleration a (s) from the memory 51, and calculates the movement distance L (s) of the sensor module 11_s within the predetermined period based on the equation (2).

Step ST6:
The processing circuit 53 calculates the direction of movement of the sensor module 11_s based on the acceleration a (s).

Step ST7:
The processing circuit 53 calculates the position (x1 (s), y1 (s)) of the sensor module 11_s at the start timing t1 of the predetermined period, the communication strength RSSI (s) 2 acquired in step ST3, and the calculation in step ST4. Based on the distance L (s) and the direction of movement of the sensor module 11_s calculated in step ST6, the position of the sensor module 11_s at the end timing t2 (x2 (x2 ( s), y2 (s)).
At this time, the position (x1 (s), y1 (s)) at the start timing t1 of the predetermined period is the value of the position (x2 (s), y2 (s)) calculated last time for the previous predetermined period. Is used.

Step ST8:
The processing circuit 53 is based on the position (x1 (s), y1 (s)) at the start timing t1 and the position (x2 (s), y2 (s)) at the end timing t2 of the predetermined period of the sensor module 11_s. The movement of the sensor module 11_s within the predetermined period is specified, and the process of specifying the user's golf form is performed based on the movement.
The processing circuit 53 may display on the display 45 a display indicating the movement locus of the sensor module 11_s for the identified form. In addition, the processing circuit 53 compares the movement path of the sensor module 11_s with a movement path prepared in advance as reference data, and displays a display that can identify the difference on the display 45.

As described above, according to the object motion detection device 1, the motion of each part of the object can be detected with high accuracy without performing image processing based on the image of the camera.
That is, in the portable terminal device 15, as described above, the distance r (s) 2 generated based on the communication strength RSSI (s) 2 with the sensor module 11_s at the end timing t2 of the predetermined period is used. The position (x2 (s), y2 (s)) at the end timing t2 of the module 11_s is calculated. Here, the position analysis based on the communication strength RSSI (s) 2 is higher in accuracy than the position analysis of the sensor alone. Therefore, the position (x2 (s), y2 (s)) can be calculated with high accuracy.
In addition, since it is not necessary to install a camera or the like in detecting the movement of the object, the work load is small and it can be used easily. Furthermore, stable and highly accurate detection is possible without being influenced by the appearance of the object.

  Moreover, in the target object motion detection apparatus 1, since the motion of the sensor modules 11_1, 11_2, and 11_3 can be detected with high accuracy, the user's golf form can be analyzed with high accuracy.

  Moreover, according to the target object motion detection apparatus 1, it can implement | achieve cheaply by using the smart phone etc. which a user owns as the portable terminal device 15, and downloading the motion detection program PRG to the portable terminal device 15. FIG.

The present invention is not limited to the embodiment described above.
That is, those skilled in the art may make various changes, combinations, sub-combinations, and alternatives regarding the components of the above-described embodiments within the technical scope of the present invention or an equivalent scope thereof.
For example, in the above-described embodiment, the case where the object motion detection device is used to detect the movement of the human body during the golf swing is exemplified. However, the movement of the human body in sports other than golf, or in the field other than sports The present invention may be applied to detect the movement of an object.

  In the embodiment described above, at least one of the acceleration signal detected by the acceleration sensor 47 of the portable terminal device 15 shown in FIG. 4 and the angular velocity signal detected by the angular velocity sensor 49 is output to the processing circuit 53, and these are used. The position of the sensor module 11_s or the portable terminal device 15 may be calculated in the processing circuit 53.

Moreover, although the case where three sensor modules were used was illustrated in embodiment mentioned above, the number of sensor modules is arbitrary.
Further, in the above-described embodiment, the case where the acceleration sensor 31_s and the angular velocity sensor 33_s are accommodated in the sensor module 11_s is illustrated, but the present invention can also be applied to the case where only the acceleration sensor 31_s is accommodated.

  Further, the communication strength RSSI may be measured between the sensor modules 11_s. This makes it possible to correct the position between the sensor modules 11_s and to correct the detection result of the sensor, and to detect the position with higher accuracy.

  The present invention is applicable to an apparatus that detects the movement of an object using an acceleration sensor.

  11_1, 11_2, 11_3 ... sensor module, 15 ... portable terminal device, 31_s ... acceleration sensor, 33_s ... angular velocity sensor, 35_s ... communication unit, 41 ... communication unit, 43 ... operation unit, 45 ... display, 47 ... acceleration sensor, 48 ... Angular velocity sensor, 51 ... Memory, 53 ... Processing circuit

Claims (9)

A motion detection program executed by a processing circuit of a communication device that receives a sensor detection result of the movement of the part from a sensor module provided in a part where the movement of the object is present,
A first procedure for obtaining a sensor detection result within a predetermined period of the sensor module;
A second procedure for obtaining a communication strength between the sensor module and the communication device at an end timing of the predetermined period;
A third procedure for calculating a first distance that the sensor module has moved within the predetermined period based on the sensor detection result acquired in the first procedure;
A fourth procedure for calculating a direction of the movement of the sensor module based on the sensor detection result obtained in the first procedure;
The first position of the sensor module at the start timing of the predetermined period, the communication strength acquired in the second procedure, the first distance calculated in the third procedure, and the fourth procedure A motion detection program for causing the processing circuit of the communication device to execute a fifth procedure for calculating the second position of the sensor module at the end timing of the predetermined period based on the direction of movement calculated in (5). When the communication device receives the sensor detection results from the plurality of sensor modules, the communication between the sensor detection results received from the sensor module and the sensor module for each of the plurality of sensor modules. Using the intensity, the processing circuit executes the processing of the first to fifth procedures to calculate the second position,
The motion detection program according to claim 1, further comprising: a sixth procedure for specifying a motion of the object based on the second positions calculated for the plurality of sensor modules. A seventh procedure for calculating a second distance between the sensor module and the communication device at an end timing of the predetermined period based on the communication intensity acquired in the second procedure;
In the fifth procedure, the distance from the first position is a virtual circle or virtual sphere centered on the third position, which is the position of the communication device, and having the radius of the second distance. Two points or circles that are the first distance are specified, and a point corresponding to the direction of movement calculated in the fourth procedure is specified as the second position among the two specified points or circles. The motion detection program according to claim 1 or 2. The motion detection program according to claim 1, wherein the sensor detection result is an acceleration detected by a sensor module. The sensor detection result further includes an angular velocity detected by the sensor module;
The motion detection program according to claim 4, wherein the fifth procedure calculates the second position by further using the angular velocity. In the fifth procedure, the virtual circle is elliptically corrected based on the acceleration and the angular velocity indicated by the sensor detection result, and the distance from the first position on the virtual ellipse obtained by the correction is The program for motion detection according to claim 5, wherein the two points or circles that become the first distance are specified. A sensor module provided in a region where the object moves,
A communication device for receiving a sensor detection result of the movement of the part from the sensor module;
The communication device
Obtaining the sensor detection result within a predetermined period from the sensor module;
Obtaining the communication strength between the sensor module and the communication device at the end timing of the predetermined period;
Based on the acquired sensor detection result, a first distance that the sensor module has moved within the predetermined period is calculated,
Based on the acquired sensor detection result, calculate the direction of the movement of the sensor module,
The predetermined period based on the first position of the sensor module at the start timing of the predetermined period, the acquired communication strength, the calculated first distance, and the calculated direction of movement. An object motion detection device that calculates a second position of the sensor module at the end timing of the object. The sensor module has an acceleration sensor;
The object motion detection device according to claim 7, wherein the sensor detection result is acceleration. A sensor module provided in a region where the object moves,
The object motion detection method using the communication device that receives the sensor detection result of the movement of the part detected by the sensor module from the sensor module,
A first step of transmitting a sensor detection result of the sensor module within a predetermined period from the sensor module to the communication device;
A second step in which the communication device acquires a communication strength between the sensor module and the communication device at an end timing of the predetermined period;
A third step in which the communication device calculates a first distance that the sensor module has moved within the predetermined period based on the sensor detection result acquired in the first step;
A fourth step in which the communication device calculates a direction of the movement of the sensor module based on the sensor detection result acquired in the first step;
The first position of the sensor module at the start timing of the predetermined period, the communication strength acquired in the second step, the first distance calculated in the third step, and the fourth step And a fifth step in which the communication device calculates a second position of the sensor module at the end timing of the predetermined period based on the direction of movement calculated in (5).