JP2015166018A - swing analyzer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a swing analyzer that can be handled easily with a comparatively simple configuration, and can determine an impact state objectively.SOLUTION: A swing analyzer 1 includes at least an angular velocity sensor 100, an attitude calculation part 202, an impact detection part 203, an attitude angle change amount calculation part 204, and an impact state determination part 205. The attitude calculation part 202 calculates an attitude of an exercise device based on output data of the angular velocity sensor 100. The impact detection part 203 detects the timing of an impact in the swing of the exercise device. The attitude angle change amount calculation part 204 calculates an amount of change in the attitude angle of the exercise device in a predetermined time from the timing of the impact based on the result of the calculation by the attitude calculation part 202. The impact state determination part 205 determines the impact state based on the result of the calculation by the attitude angle change amount calculation part 204.

Description

  The present invention relates to a swing analyzer.

  In sports such as tennis, baseball, and golf, by capturing the ball at a sweet spot of an exercise equipment (ball striking tool), the speed and distance of the ball can be increased and the competitiveness can be improved. Until now, athletes have learned to swing to catch a ball at a sweet spot by repeating swing exercises. However, whether or not the ball hits the sweet spot is left to the subjective judgment of the competitors and coaches, so it may not always be an efficient practice.

  On the other hand, in recent years, a method has been proposed in which an exercise apparatus with a mark is photographed with a camera, and the state of impact is measured by analyzing the photographed video. Can be objectively determined. For example, in Patent Document 1, a system is provided in which a plurality of marks are provided on the face of a golf club head, images before and after impact are photographed with a CCD camera or the like, and the impact position on the face surface is calculated from the photographed images at the time of impact. Has been proposed.

JP 2004-24488 A

  However, such a system is expensive because it requires a camera to shoot video, and is costly, and it is difficult to handle because it is necessary to arrange the camera according to the angle at which it is desired to shoot. There is a problem.

  The present invention has been made in view of the above problems, and according to some aspects of the present invention, it is easy to handle with a relatively simple configuration and objectively determines the state of impact. It is possible to provide a swing analysis apparatus that can perform the above.

  (1) The present invention provides an angular velocity sensor, a posture calculation unit that calculates the posture of the exercise equipment based on output data of the angular velocity sensor, and an impact detection unit that detects the timing of impact in the swing of the exercise equipment; A posture angle change amount calculation unit that calculates a change amount of the posture angle of the exercise equipment within a predetermined time from the timing of the impact based on a calculation result of the posture calculation unit; and a calculation of the posture angle change amount calculation unit The swing analysis device includes an impact state determination unit that determines the state of the impact based on the result.

  According to the swing analysis device of the present invention, the rotational movement of the exercise equipment immediately after the impact with respect to the predetermined axis can be grasped as the amount of change in the posture angle, so that by appropriately selecting the predetermined axis according to the exercise equipment It is possible to objectively determine the state of impact. Further, according to the swing analyzer of the present invention, since an angular velocity sensor is used instead of a camera, a simple configuration can be achieved and handling is easy.

(2) In this swing analysis device, the impact detection unit detects the maximum value of the magnitude of the angular velocity with respect to the swing axis of the exercise equipment based on the output data of the angular velocity sensor, and as the timing of the impact, You may make it detect the timing when the magnitude | size of the angular velocity with respect to the axis | shaft of the swing of the said exercise equipment becomes the maximum.

  In general, it is considered that the angular velocity with respect to the swing axis of the exercise equipment is maximized immediately before the impact. Therefore, according to this swing analyzer, the timing of the impact can be detected.

  (3) In this swing analyzer, the impact state determination unit variably sets the determination criterion of the impact state according to the maximum value of the angular velocity with respect to the swing axis of the exercise equipment. Also good.

  In general, if the swing speed of the exercise equipment is different, even if the ball hits the same position, the amount of change in the posture angle due to the generated rotational motion is considered to be different. According to this swing analyzer, the impact state can be determined without error by using an appropriate determination criterion according to the swing speed.

  (4) In this swing analysis apparatus, the impact state determination unit may determine the state of impact at a plurality of levels.

  In this way, the user can obtain not only information on whether the meet has succeeded or failed, but also information on how much the meet has failed.

  (5) In this swing analyzer, the angular velocity sensor may be attached to the exercise equipment such that the detection axis is the swing axis of the exercise equipment.

  In this way, since the swing axis of the exercise equipment is known, processing for calculating the axis is not necessary.

  (6) The swing analysis apparatus further includes a rotation axis calculation unit that calculates at least one of an axis to be calculated for the posture angle and a swing axis of the exercise equipment based on the posture information of the exercise equipment. You may make it.

  For example, in a sports equipment in which the ball striking surface changes depending on how it is gripped, such as a baseball bat, it is not possible to specify the ball striking surface. The positional relationship between the detection axis of the angular velocity sensor and the detection axis of the angular velocity sensor differs depending on the swing. Further, for example, the positional relationship between the swing axis of the exercise equipment and the detection axis of the angular velocity sensor differs depending on the swing due to the inclination of the exercise equipment during the swing. According to this swing analysis apparatus, by calculating the posture of the exercise equipment, it is possible to calculate the posture angle of the axis or the exercise equipment without limiting the angle at which the exercise equipment is gripped or the inclination of the exercise equipment during the swing. The swing axis can be specified.

The figure which shows the structure of the swing analyzer of this embodiment. The flowchart figure which shows an example of the process by a process part. Explanatory drawing of the example which determines the impact state in the swing of a tennis racket. The figure which shows the example of actual measurement of angular velocity data at the time of failing a meet. The figure which shows the example of an actual measurement of the attitude angle of the tennis racket at the time of just meet. The figure which shows the actual measurement example of the attitude angle of the tennis racket at the time of failing a meet. The flowchart figure of the specific example which determines the state of the impact of this embodiment. Explanatory drawing of the example which determines the impact state in the swing of a bat. Explanatory drawing of the example which determines the impact state in the swing of a golf club. The figure which shows the structure of the swing analyzer of the modification 1. The flowchart figure which shows an example of the process by the process part of the modification 1. The flowchart figure of the specific example which determines the state of the impact of the modification 1.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. The embodiments described below do not unduly limit the contents of the present invention described in the claims. Also, not all of the configurations described below are essential constituent requirements of the present invention.

1. Configuration of Swing Analyzer FIG. 1 is a diagram showing a configuration of a swing analyzer according to this embodiment. The swing analysis apparatus 1 according to the present embodiment includes one or a plurality of sensor units 10 and a host terminal 20. The sensor unit 10 and the host terminal 20 may be wirelessly connected or wired.

  The sensor unit 10 is attached to an exercise device to be subjected to swing analysis. In the present embodiment, the sensor unit 10 includes one or more angular velocity sensors 100, a data processing unit 110, and a communication unit 120.

  The angular velocity sensor 100 detects an angular velocity around the detection axis and outputs a signal (angular velocity data) corresponding to the detected angular velocity. In the swing analysis apparatus 1 of the present embodiment, the sensor unit 10 detects, for example, angular velocities in three axis directions (x axis, y axis, z axis) in order for the host terminal 20 to calculate the posture of the exercise equipment. Three angular velocity sensors 100 are included.

  The data processing unit 110 performs processing of synchronizing output data of the angular velocity sensor 100 and outputting the data to the communication unit 120 as a packet combined with time information and the like. Further, the data processing unit 110 may perform bias correction and temperature correction processing of the angular velocity sensor 100. Note that functions of bias correction and temperature correction may be incorporated in the angular velocity sensor 100.

  The communication unit 120 performs processing for transmitting the packet data received from the data processing unit 110 to the host terminal 20.

  The host terminal 20 includes a processing unit (CPU) 200, a communication unit 210, an operation unit 220, a ROM 230, a RAM 240, a nonvolatile memory 250, and a display unit 260. The host terminal 20 can be realized by a personal computer (PC) or a mobile device such as a smartphone.

  The communication unit 210 performs processing of receiving data transmitted from the sensor unit 10 and sending the data to the processing unit 200.

  The operation unit 220 performs a process of acquiring operation data from the user and sending it to the processing unit 200. The operation unit 220 is, for example, a touch panel display, buttons, keys, a microphone, and the like.

  The ROM 230 stores programs for the processing unit 200 to perform various calculation processes and control processes, various programs and data for realizing application functions, and the like.

  The RAM 240 is used as a work area of the processing unit 200, and temporarily stores programs and data read from the ROM 230, data input from the operation unit 220, calculation results executed by the processing unit 200 according to various programs, and the like. It is a storage unit.

  The non-volatile memory 250 is a recording unit that records data that needs to be stored for a long time among the data generated by the processing of the processing unit 200.

  The display unit 260 displays the processing result of the processing unit 200 as characters, graphs, or other images. The display unit 260 is, for example, a CRT, LCD, touch panel display, HMD (head mounted display), or the like. Note that the functions of the operation unit 220 and the display unit 260 may be realized by a single touch panel display.

  The processing unit 200 performs various calculation processes on the data received from the sensor unit 10 via the communication unit 210 and various control processes (such as display control for the display unit 260) according to a program stored in the ROM 240.

  In the present embodiment, the processing unit 200 functions as a data acquisition unit 201, an impact detection unit 203, an attitude calculation unit 203, an attitude angle change amount calculation unit 204, and an impact state determination unit 205 described below. Note that the processing unit 200 of the present embodiment may have a configuration in which some of these functions are omitted.

  The data acquisition unit 201 performs processing for acquiring output data (angular velocity data) of the sensor unit 10 received via the communication unit 210. The acquired data is stored in the RAM 240, for example.

  The impact detection unit 203 performs processing for detecting the timing of impact (hereinafter simply referred to as “impact”) in the swing of the exercise equipment.

  The posture calculation unit 203 performs a process of calculating the posture of the exercise equipment based on output data (angular velocity data for three axes) of the sensor unit 10.

  The posture angle change amount calculation unit 204 performs a process of calculating the change amount of the posture angle of the exercise equipment within a predetermined time from the timing of impact based on the calculation result of the posture calculation unit 203.

  The impact state determination unit 205 performs a process of determining the impact state based on the calculation result of the posture angle change amount calculation unit 204.

  Note that all or part of the data acquisition unit 201, impact detection unit 203, posture calculation unit 203, posture angle change amount calculation unit 204, and impact state determination unit 205 may be in the sensor unit 10.

  FIG. 2 is a flowchart illustrating an example of processing performed by the processing unit 200. First, the processing unit 200 acquires angular velocity data from the sensor unit 10 as the data acquisition unit 201 (S10, angular velocity data acquisition step).

  Next, the processing unit 200 calculates the posture of the exercise equipment as the posture calculation unit 202 based on the angular velocity data acquired in S10 (S20, posture calculation step). Since the sensor unit 10 is fixed to the exercise device, the posture of the sensor unit 10 may be calculated as the posture of the exercise device, or the posture of a predetermined part of the exercise device (for example, a ball hitting surface) Angle, etc.) may be calculated.

  Next, the processing unit 200 detects the timing of impact as the impact detection unit 203 (S30, impact detection step). For example, the processing unit 200 (impact detection unit 203), based on the output data (angular velocity data) of the sensor unit 10, the maximum value of the magnitude of the angular velocity relative to the swing axis of the exercise equipment (hereinafter referred to as “swing axis”). And the timing at which the magnitude of the angular velocity with respect to the swing axis is maximized may be detected as the impact timing. In addition, you may attach the sensor part 10 to an exercise device so that the detection axis of any angular velocity sensor 100 may become a swing axis.

  Next, the processing unit 200 calculates, as the posture angle change amount calculation unit 204, the amount of change in the posture angle of the exercise equipment within a predetermined time from the timing of impact based on the posture information of the exercise equipment calculated in S20. (S40, posture angle change amount calculating step). The sensor unit 10 may be attached to the exercise equipment such that the detection axis of any one of the angular velocity sensors 100 is an axis for calculating the posture angle of the exercise equipment.

  Finally, the processing unit 200 determines an impact state as the impact state determination unit 205 based on the calculation result in S40 (S50, impact state determination step). For example, the processing unit 200 (impact state determination unit 205) may variably set the determination criterion for the impact state according to the maximum value of the angular velocity with respect to the swing axis. Further, for example, the processing unit 200 (impact state determination unit 205) may determine the impact state at a plurality of levels. Then, for example, the processing unit 200 may display the determination result of the impact state on the display unit 260 or may output it as a sound.

2. Specific Example Next, the method of the present embodiment will be described with reference to an example in which an impact state in a swing of a tennis racket is determined. FIG. 3A shows a view in which the tennis ball 3 hits a position on the long axis (indicated by a one-dot chain line) of the tennis racket 2 in the swing of the tennis racket 2. On the other hand, FIG. 3B shows a view in which the tennis ball 3 hits a position shifted downward from the long axis (indicated by a one-dot chain line) of the tennis racket 2 in the swing of the tennis racket 2. When the tennis ball 3 hits the position on the long axis of the tennis racket 2 (just met), the rotation around the long axis hardly occurs, but when the tennis ball 3 hits the position shifted from the long axis ( In the case of the failure of the meet), rotation around the major axis (arrow in FIG. 3B) occurs immediately after the impact. Therefore, it can be determined whether or not the tennis ball 3 has hit the major axis from the amount of change in the posture angle of the axis orthogonal to the major axis immediately after the impact. An axis that can determine the state of impact from the amount of change in the posture angle immediately after the impact, such as an axis orthogonal to the major axis of the tennis racket 2, is hereinafter referred to as a “determination axis”.

  The impact timing can be determined from the angular velocity around the swing axis. In the case of a swing of a tennis racket, an axis that is perpendicular and upward to the long axis of the tennis racket 2 may be considered as a swing axis. In the case of a tennis racket swing, the absolute value of the angular velocity around the swing axis gradually increases from the start of the swing until the moment of impact, and when the tennis ball 3 hits the tennis racket 2 at the moment of impact, the swing axis The absolute value of the angular velocity around is small. That is, the impact timing can be detected because the absolute value of the angular velocity around the swing axis is maximum immediately before the impact.

Therefore, in order to capture the angular velocity around the swing axis and the attitude angle of the determination axis, for example, a sensor including three angular velocity sensors that can respectively detect angular velocities in three orthogonal directions (x-axis, y-axis, and z-axis). The part 10 is attached to the position of the grip end of the tennis racket 2 so that, for example, the x-axis is perpendicular to the hitting surface and the z-axis is coincident with the long axis of the tennis racket 2. As a result, the impact timing can be detected from the maximum angular velocity around the y-axis (swing axis), and the impact state can be determined from the amount of change in the attitude angle of the x-axis or z-axis (determination axis) immediately after the impact. Can be determined. In addition, the sensor part 10 can be attached not only to the position of the grip end of the tennis racket 2 but also to an arbitrary position that does not hinder the swing.

FIG. 4 is a diagram illustrating an actual measurement example of the triaxial angular velocity data. Reference numerals 40x, 40y, and 40z denote angular velocity data about the x axis, angular velocity data about the y axis, and angular velocity data about the z axis, respectively. The time t _{0 at} which the absolute value of the angular velocity around the y-axis is maximized is the impact timing. The data shown in FIG. 4 is obtained when the meet fails, and the angular velocity around the z axis changes greatly immediately after the impact. That is, when the meet fails, it is considered that the amount of change in the posture angle of the x-axis and y-axis immediately after the impact is large. Note that the amount of change in the posture angle when the meet fails depends on the weight of the tennis racket 2. For example, if the weight of the tennis racket 2 is light, the change amount of the posture angle when the meet fails is large. On the other hand, if the tennis racket is heavy, the change amount of the posture angle when the meet fails is small.

5 and 6 are graphs obtained by calculating the angle of the striking surface (face) of the tennis racket 2 from the measured values of the triaxial angular velocities when the just meet and when the meet fails, respectively. The angle of the hitting surface (face) of the tennis racket 2 corresponds to the attitude angle of the y-axis. Comparing FIG. 5 and FIG. 6, it can be seen that there is a large difference in the amount of change in the attitude angle of the y-axis immediately after the impact, and the amount of change is greater when the meet fails. Therefore, in this embodiment, the amount of change in the attitude angle of the x-axis or y-axis in the period from the impact timing t ₀ to the time t ₁ after a predetermined time T (for example, 0.05 seconds) has been calculated. Specifically, the maximum value Δθ _max of the attitude angle change amount with respect to the x-axis or y-axis attitude angle θ ₀ at the impact timing t ₀ at a predetermined time T is calculated. Then, the state of impact is determined from the magnitude of this Δθ _max .

  FIG. 7 shows a specific example of a flowchart for determining the state of impact by the processing unit 200. In the example of FIG. 7, the impact state is determined by dividing it into three levels. First, the processing unit 200 periodically acquires new triaxial angular velocity data from the sensor unit 10 until the data acquisition period ends (N in S112) (S110). The data acquisition period is a predetermined period including at least before and after the impact. For example, the data acquisition period may be a period from the start to the end of the swing, and further, the rest period before the start of the swing or the rest after the end of the swing. You may make it include until a period.

  Next, the processing unit 200 calculates the attitude of the sensor unit 10 based on the triaxial angular velocity data acquired in S110 (S120). For example, the initial posture of the sensor unit 10 in the xyz coordinate system is appropriately defined, and the posture is calculated by integrating the posture change from the initial posture of the sensor unit 10 in the xyz coordinate system from the time series of the triaxial angular velocity data. calculate. Note that a triaxial acceleration sensor may be provided in the sensor unit 10, and the initial posture may be determined by detecting the direction of gravitational acceleration when the exercise apparatus is stationary.

  Next, the processing unit 200 detects a timing (impact timing) at which the absolute value of the angular velocity around the y-axis (swing axis) is maximized based on the triaxial angular velocity data acquired in S110 (S130).

Next, the processing unit 200 determines impact level determination levels (determination criteria) L1 and L2 based on the maximum angular velocity (maximum value of the angular velocity) about the y-axis (swing axis) (S132). That is, there is a correlation between the magnitude of the maximum angular velocity around the y-axis (swing axis) (swing speed) and the amount of change in the attitude angle of the x-axis or y-axis (determination axis) immediately after impact. Since it is conceivable, the determination levels L1 and L2 of the impact state are variably set according to the speed of the swing.

Next, the processing unit 200 calculates the maximum posture angle change amount Δθ _max of the x axis or the y axis (determination axis) at a predetermined time T from the impact timing detected in S130 (S140).

The processing section 200 compares the determination level L1, L2 determining the [Delta] [theta] _max in step S132, if the [Delta] [theta] _max <L1 (in S150 Y), Meat successful (e.g., Just meet) and determines (S152) . Further, if L1 ≦ Δθ _max <L2 (N in S150 and Y in S154), the processing unit 200 determines that the meet has failed (level 1) (for example, slightly deviated from just meet) (S156). If Δθ _max ≧ L2 (N in S150 and N in S154), the processing unit 200 determines that the meet has failed (level 2) (for example, significantly deviated from just meet) (S158). In this way, by setting a plurality of determination levels, the user can obtain not only information on whether the meet has succeeded or failed, but also information on how much failure has occurred when the meet has failed.

  Note that S110 and S112 in the flowchart in FIG. 7 correspond to S10 (angular velocity data acquisition step) in the flowchart in FIG. Further, S120 in the flowchart of FIG. 7 corresponds to S20 (attitude calculation step) in the flowchart of FIG. Further, S130 in the flowchart of FIG. 7 corresponds to S130 (impact detection step) in the flowchart of FIG. 7 corresponds to S40 (posture angle change amount calculating step) in the flowchart of FIG. Further, S150, S152, S154, S156, and S158 in the flowchart of FIG. 7 correspond to S50 (impact state determination step) in the flowchart of FIG.

  In the present embodiment, the swing axis and the determination axis have been described as matching with the detection axis of one of the angular velocity sensors 100. However, depending on the mounting position and mounting angle of the sensor unit 10, these may not match. is there. In such a case, a deviation between the swing axis or the determination axis and the detection axis may be corrected using a correction parameter created in advance.

  In the above, the method of this embodiment has been described by taking the case where the exercise equipment is a tennis racket as an example, but for other exercise equipment, if the swing axis and the determination axis are appropriately defined according to the exercise equipment, The method of this embodiment can be applied.

  For example, FIG. 8A shows a view in which the ball 5 hits a position on the long axis (indicated by a one-dot chain line) of the bat 4 in the swing of the baseball bat 4. On the other hand, FIG. 8B shows a view in which the ball 5 hits a position shifted upward from the long axis (indicated by the alternate long and short dash line) of the bat 4 in the swing of the bat 4. When the ball 5 hits the position on the long axis of the bat 4 (just met), there is almost no rotation around the axis perpendicular to both the long axis and the swing axis (the axis in the direction of travel of the bat 4). When the ball 5 hits a position deviated from the major axis (when the meat fails), rotation around the axis in the traveling direction of the bat 4 (arrow in FIG. 8B) occurs immediately after the impact. Therefore, it is possible to determine whether or not the tennis ball 3 has hit the major axis from the amount of change in the attitude angle of the determination axis, with an arbitrary axis orthogonal to the axis of the advancing direction of the bat 4 immediately after the impact as the determination axis. . Further, the impact timing can be determined from the angular velocity around the swing axis as in the case of the tennis racket.

Therefore, in order to capture the angular velocity around the swing axis and the attitude angle of the determination axis, for example, a sensor including three angular velocity sensors that can respectively detect angular velocities in three orthogonal directions (x-axis, y-axis, and z-axis). The part 10 is attached to the position of the grip end of the bat 4 such that the z axis coincides with the long axis of the bat 4. Then, when the subject swings by holding the bat 4 so that the x-axis and the y-axis coincide with the determination axis and the swing axis, respectively, at the moment of impact, the impact timing is determined from the angular velocity data around the y-axis (swing axis). Can be detected, and the state of impact can be determined from the amount of change in the posture angle of the y-axis or z-axis (determination axis) immediately after impact. In addition, the sensor part 10 can be attached not only to the position of the grip end of the bat 4 but also to an arbitrary position that does not hinder the swing.

  For example, FIG. 9A shows a view in which the golf ball 7 hits a position on the central axis (indicated by a one-dot chain line) of the head of the golf club 6 in the swing of the golf club 6. On the other hand, FIG. 9B shows a view in which the golf ball 7 hits a position shifted leftward from the center axis (indicated by the alternate long and short dash line) of the head of the golf club 6 in the swing of the golf club 6. . When the golf ball 7 hits the position on the central axis of the head of the golf club 6 (just met), the rotation around the central axis hardly occurs, but the golf ball 7 hits the position shifted from the central axis. In this case (when the meet fails), a rotation around the central axis (an arrow in FIG. 9B) occurs immediately after the impact. Therefore, it is determined whether or not the golf ball 7 has hit the central axis from the amount of change in the attitude angle of the determination axis with an arbitrary axis orthogonal to the central axis of the head of the golf club 6 immediately after impact as the determination axis. it can. Further, the impact timing can be determined from the angular velocity around the swing axis as in the case of the tennis racket.

  Therefore, in order to capture the angular velocity around the swing axis and the angular velocity around the determination axis, for example, a sensor including three angular velocity sensors that can detect angular velocities in three orthogonal directions (x-axis, y-axis, and z-axis), respectively. The portion 10 is attached to the head of the golf club 6 such that, for example, the x-axis is perpendicular to the ball striking surface and the z-axis is coincident with the central axis of the golf club 6 head. Thereby, the impact timing can be detected from the angular velocity data around the y-axis (swing axis), and the impact state is determined from the amount of change in the attitude angle of the x-axis or y-axis (determination axis) immediately after the impact. be able to. In addition, the sensor part 10 can be attached not only to the head of the golf club 6 but at an arbitrary position that does not hinder the swing.

  As described above, according to the swing analysis device of the present embodiment, by calculating the maximum amount of change in the attitude angle of the determination axis in a predetermined time immediately after the impact, the rotational motion of the exercise apparatus caused by the impact is captured. Can do. Therefore, the impact state can be objectively determined by appropriately selecting the determination axis according to the exercise equipment. Further, according to the swing analysis apparatus of the present embodiment, since the angular velocity sensor is used instead of the camera used in the conventional system, a simpler configuration can be achieved and the handling is easy.

3. The present invention is not limited to this embodiment, and various modifications can be made within the scope of the present invention.

3-1. Modification 1
In the present embodiment, the swing axis and the determination axis have been described as matching with the detection axis of one of the angular velocity sensors 100, but these may not match depending on the shape of the exercise equipment and the state of the swing. For example, as shown in FIGS. 3 (A) and 3 (B), when the sensor unit 10 is attached to the grip end of a tennis racket, the swinging surface is swung horizontally while keeping the hitting surface perpendicular to the swing surface. Then, the y-axis and the judgment axis coincide with each other. Also, in the case of an exercise apparatus that cannot specify a ball striking surface such as a baseball bat, if the angle at which the exercise apparatus is gripped is not determined, at least one of the swing axis and the determination axis does not coincide with the detection axis of the angular velocity sensor 100 There is also. Therefore, in the swing analysis apparatus of the first modification, the swing axis and the determination axis are calculated from the posture change of the exercise equipment, and the impact state is determined.

  FIG. 10 is a diagram illustrating the configuration of the swing analyzer according to the second modification. In the swing analysis device 1 of the second modification, the processing unit 200 functions as a data acquisition unit 201, a posture calculation unit 202, an impact detection unit 203, a posture angle change amount calculation unit 204, and an impact state determination unit 205. It functions as the rotation axis calculation unit 206.

  The rotation axis calculation unit 206 performs a process of calculating at least one of a determination axis (an axis for which a posture angle is calculated) and a swing axis based on the posture information of the exercise equipment calculated by the posture calculation unit 205. The other configuration of the swing analyzer according to the second modification is the same as that shown in FIG.

  Note that all or part of the data acquisition unit 201, posture calculation unit 202, impact detection unit 203, posture angle change amount calculation unit 204, impact state determination unit 205, and rotation axis calculation unit 206 may be in the sensor unit 10. Good.

  FIG. 11 is a flowchart illustrating an example of processing performed by the processing unit 200 in the swing analyzer 1 according to the first modification. First, the processing unit 200 acquires angular velocity data from the sensor unit 10 as the data acquisition unit 201 (S10, angular velocity data acquisition step).

  Next, the processing unit 200 calculates the posture of the exercise equipment as the posture calculation unit 202 based on the angular velocity data acquired in S10 (S20, posture calculation step).

  Next, the processing unit 200 calculates at least one of the determination axis and the swing axis as the rotation axis detection unit 206 (S22, rotation axis calculation step).

  Next, the processing unit 200 detects the timing of impact as the impact detection unit 203 (S30, impact detection step). For example, the processing unit 200 (impact detection unit 203) detects the timing at which the magnitude of the angular velocity with respect to the swing axis calculated in S22 is the maximum as the impact timing.

  Next, the processing unit 200 calculates, as the posture angle change amount calculation unit 204, the amount of change in the posture angle of the exercise equipment within a predetermined time from the timing of impact based on the posture information of the exercise equipment calculated in S20. (S40, posture angle change amount calculating step). For example, the processing unit 200 (posture angle change amount calculation unit 204) detects the change amount of the posture angle of the determination axis calculated in S22.

  Finally, the processing unit 200 determines an impact state as the impact state determination unit 205 based on the calculation result in S40 (S50, impact state determination step).

  FIG. 12 shows a specific example of a flowchart for determining the state of impact by the processing unit 200 of the first modification. In the example of FIG. 12, the impact state is determined by dividing it into three levels. First, the processing unit 200 periodically acquires new triaxial angular velocity data from the sensor unit 10 until the data acquisition period ends (N in S212) (S210).

  Next, the processing unit 200 calculates the attitude of the sensor unit 10 based on the triaxial angular velocity data acquired in S210 (S220).

Next, the processing unit 200 calculates a swing axis and a determination axis based on the posture information of the sensor unit 10 calculated in S220 (S222). For example, the central axis of the rotational movement of the sensor unit 10 due to the swing is calculated from the change in posture of the sensor unit 10 in the xyz coordinate system. This central axis becomes the swing axis. Further, since the attitude of the sensor unit 10 in the xyz coordinate system changes due to the impact, the determination axis can be calculated from the direction of the attitude change.

  Next, the processing unit 200 calculates an angular velocity around the swing axis based on the triaxial angular velocity data acquired in S210 (S230). Since the angular velocity data for the x-axis, y-axis, and z-axis and the swing axis in the xyz coordinate system are known, the angular velocity around the swing axis can be calculated by known calculation.

  Next, the processing unit 200 detects the timing (impact timing) at which the absolute value of the angular velocity around the swing axis is maximized (S232).

  Next, the processing unit 200 determines the impact state determination levels L1 and L2 based on the maximum angular velocity around the swing axis (the maximum value of the absolute value of the angular velocity) (S234).

Next, the processing unit 200 calculates the maximum posture change amount Δθ _max of the determination axis at the predetermined time T from the impact timing detected in S232 (S240).

Then, the processing unit 200 compares Δω _max with the determination levels L1 and L2 determined in step S234, and determines Δmeat success (for example, just meet) if Δθ _max <L1 (Y in S250) (S252). . Further, if L1 ≦ Δθ _max <L2 (N in S250 and Y in S254), the processing unit 200 determines that the meet has failed (level 1) (for example, slightly deviated from just meet) (S256). If Δθ _max ≧ L2 (N in S250 and N in S254), the processing unit 200 determines that the meet has failed (level 2) (for example, significantly deviated from just meet) (S258).

  As described above, by calculating the sensor unit 10 (that is, the posture of the exercise equipment), the swing axis and the determination axis can be calculated regardless of the shape of the exercise equipment and the swing state. Can be judged well.

  Note that S210 and S212 in the flowchart in FIG. 12 correspond to S10 (angular velocity data acquisition step) in the flowchart in FIG. Further, S220 in the flowchart in FIG. 12 corresponds to S20 (attitude calculation step) in the flowchart in FIG. Further, S222 in the flowchart of FIG. 12 corresponds to S22 (rotation axis calculation step) in the flowchart of FIG. Further, S230 and S232 in the flowchart of FIG. 12 correspond to S30 (impact detection step) in the flowchart of FIG. 12 corresponds to S40 (attitude angle change amount calculating step) in the flowchart of FIG. Further, S250, S252, S254, S256, and S258 in the flowchart of FIG. 12 correspond to S50 (impact state determination step) in the flowchart of FIG.

3-2. Other Modifications For example, as shown in FIG. 1, in the swing analyzer of the present embodiment, the sensor unit 10 and the host terminal 20 are connected wirelessly or by wire, but the sensor unit 10 and the host terminal 20 are connected to each other. An interface unit for the memory card is provided, and the sensor unit 10 writes the output data of the angular velocity sensor 100 to the memory card, and the host terminal 20 reads the data from the memory card and performs the impact state determination process. Good. Alternatively, the function of the processing unit 200 of the host terminal 20 may be incorporated in the sensor unit 10.

  Further, in the swing analysis device of the present embodiment, after the processing unit 200 acquires all necessary angular velocity data, the impact state determination process is performed. However, every time the processing unit 200 acquires the angular velocity data, the impact state is determined. This determination process may be performed in real time.

  Further, in the swing analysis device of the present embodiment, the impact timing is detected based on the angular velocity around the swing axis, but the acceleration sensor is attached to the exercise equipment such that the detection axis is perpendicular to the striking surface, for example. Based on the output data of the acceleration sensor, for example, the timing at which the maximum acceleration is reached may be detected as the impact timing. In the case of an exercise device for which the ball striking face cannot be specified, a 3-axis acceleration sensor is attached to the exercise device (a 2-axis acceleration sensor may be used depending on the attachment position), an acceleration vector at a predetermined position of the exercise device is calculated, and the magnitude of the acceleration vector is calculated. Based on this, the impact timing can be detected.

  Further, in the swing analysis device of the present embodiment, the impact state is determined based on the amount of change in the attitude angle of the determination axis immediately after the impact, but it cannot be accurately determined whether or not the ball hits the sweet spot. There is also a possibility. For example, in the case of a swing of a tennis racket, there is a possibility that it is determined that the meet is successful because the amount of change in the posture angle of the determination axis is small regardless of the position on the long axis of the tennis racket. Generally, when the position where the ball hits deviates from the sweet spot, it is considered that the vibration generated in the exercise equipment increases. The magnitude of this vibration can be detected from the change in angular velocity around the swing axis immediately after impact. Therefore, based on the angular velocity around the determination axis immediately after the impact and the angular velocity around the swing axis, it may be determined whether or not the sweet spot has been hit or how far away from the sweet spot the ball has hit. Good.

  The present invention includes configurations that are substantially the same as the configurations described in the embodiments (for example, configurations that have the same functions, methods, and results, or configurations that have the same objects and effects). In addition, the invention includes a configuration in which a non-essential part of the configuration described in the embodiment is replaced. In addition, the present invention includes a configuration that exhibits the same operational effects as the configuration described in the embodiment or a configuration that can achieve the same object. Further, the invention includes a configuration in which a known technique is added to the configuration described in the embodiment.

DESCRIPTION OF SYMBOLS 1 Swing analyzer, 2 Tennis racket, 3 Tennis ball, 4 Bat, 5 Ball, 6 Golf club, 7 Golf ball, 10 Sensor part, 20 Host terminal, 100 Angular velocity sensor, 110 Data processing part, 120 Communication part, 200 process Unit (CPU), 201 data acquisition unit, 202 posture calculation unit, 203 impact detection unit, 204 posture angle change calculation unit, 205 impact state determination unit, 206 rotation axis calculation unit, 210 communication unit, 220 operation unit, 230 ROM 240 RAM, 250 Non-volatile memory, 260 Display unit

Claims (6)

Angular velocity sensor,
A posture calculating unit that calculates a posture of the exercise apparatus based on output data of the angular velocity sensor;
An impact detector for detecting the timing of impact in the swing of the exercise equipment;
A posture angle change amount calculation unit that calculates a change amount of the posture angle of the exercise equipment within a predetermined time from the timing of the impact based on the calculation result of the posture calculation unit;
A swing analysis apparatus comprising: an impact state determination unit that determines the state of the impact based on a calculation result of the posture angle change amount calculation unit. In claim 1,
The impact detector
Based on the output data of the angular velocity sensor, the maximum value of the angular velocity with respect to the swing axis of the exercise equipment is detected, and the magnitude of the angular velocity with respect to the swing axis of the exercise equipment is the maximum as the impact timing. Swing analyzer that detects the timing. In claim 2,
The impact state determination unit
A swing analysis device that variably sets a determination criterion for the state of impact according to a maximum value of an angular velocity with respect to a swing axis of the exercise equipment. In any one of Claims 1 thru | or 3,
The impact state determination unit
A swing analyzer that determines the state of impact at a plurality of levels. In any one of Claims 1 thru | or 4,
The angular velocity sensor is attached to the exercise equipment such that a detection axis is an axis of swing of the exercise equipment. In any one of Claims 1 thru | or 5,
The swing analysis apparatus further includes a rotation axis calculation unit that calculates at least one of an axis that is a calculation target of the attitude angle and a swing axis of the exercise instrument based on information on the attitude of the exercise instrument.