JP5471357B2 - Golf club swing display method and display chart - Google Patents

Description

  The present invention relates to a golf club swing display method and display chart.

Conventionally, as a method of measuring and analyzing a golf swing, a method of capturing a golf swing with a camera, analyzing a behavior of the golf club head from the captured image, and extracting a feature of the golf swing, or a golf club head with a magnetic sensor A method for directly measuring the behavior of a golf club, or a method for measuring the behavior of a golf club head using an interrupter type optical sensor that senses that a plurality of light beams arranged at predetermined positions pass across the golf club head. Can be mentioned.
All of these can measure the approximate trajectory of the golf club head, but cannot accurately grasp the behavior of the golf club head immediately before the golf ball hitting the golf ball.

On the other hand, Patent Documents 1 and 2 below describe devices that can measure the behavior of a golf club when a golf ball is hit.
As described in [0023] of Patent Document 1, by arranging four sensors, it is possible to roughly know the incident angle of the golf club head with respect to the golf ball. Similarly, in Patent Document 2, it is possible to roughly know the incident angle of the golf club head with respect to the golf ball by arranging four sensors.

JP 2001-314540 A Japanese Patent No. 3073828

  However, in the measurement of the behavior of the golf club according to Patent Documents 1 and 2, although the golf club head can roughly know the incident angle of the golf club head with respect to the golf ball, the golf that affects the spherical muscles such as the hook and slice of the golf ball. It was difficult to easily understand the characteristics of the club swing.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide golf that is advantageous in providing easily and easily understandable swing characteristics that affect the ball muscles such as hooks and slices of golf balls. It is intended to provide a club swing display method and display chart.

In order to achieve the above object, the present invention displays on a display device swing characteristics measured based on the behavior of a golf club head immediately before the golf club head of a golf club swung by a golfer hits a golf ball. A method for displaying a swing of a golf club, comprising: a reference line obtained by projecting a target line connecting the center of the golf ball and a target onto a plane parallel to a horizontal plane; and the golf club head immediately before hitting the golf ball. The angle formed by the first straight line projected on the plane with the tangent to the movement trajectory is the left and right approach angle, and the sign of the left and right approach angle is the positive angle on the opposite side of the golfer with the reference line as the center. Is a negative angle, and the golf club head fades immediately before hitting the golf ball with the reference line. The angle formed by the normal line passing through the center point of the surface and the second straight line projected on the plane is the face angle at the time of hitting, and the positive / negative of the face angle at the time of hitting is positive on the opposite side of the golfer around the reference line. When the golfer side is a negative angle, the display screen of the display device has an X axis indicating the left and right approach angle and a Y axis perpendicular to the X axis and indicating the face angle at the time of hitting. A coordinate axis display step for displaying a two-dimensional coordinate axis in which the intersection of the X axis and the Y axis is set to the left and right approach angles and the hitting face angle of zero degrees, and a plurality of boundaries divided on the display screen according to the tendency of the spherical muscles Various area display steps for displaying the area, and coordinates indicating the left and right approach angle values and the hit face angle values measured when the golfer hits a golf ball with a golf club on the display screen Dot And a measurement point display step of displaying a fixed point, before the various areas displaying step is performed on the display screen, is defined by a positive portion and positive part of the Y-axis of the X-axis in the two-dimensional coordinate axes A first boundary line through which the left and right approach angles and the hitting face angle extend from a negative region to a positive region through a fixed point defined in the first quadrant, the left and right approach angles and An area where the face angle at the time of hitting is negative or an area where the left and right approach angle is negative and an area where the face angle at hitting is positive is included in this area extends with a smaller slope than the first boundary line. A second boundary line intersecting with a fixed point, and a third boundary line extending from the fixed point to a region where the left and right approach angles and the hitting face angle are positive with an inclination smaller than the inclination of the first boundary line Border display step The display of a plurality of areas demarcated according to the tendency of the spherical muscles in the various area display steps is a straight line portion located in a positive area of the face angle at the time of hitting in the first boundary line And a region sandwiched by the second boundary line is displayed as a slice area, and a straight line portion located in a negative region of the face angle at the time of striking of the first boundary line and the second boundary A region sandwiched between lines is displayed as a fade area, and a region sandwiched between the first boundary line and the straight line portion located in the negative region of the face angle at the time of hitting and the third boundary line Is displayed as a hook area, and a region sandwiched between the straight line portion of the first boundary line located in the positive region of the face angle at the time of hitting and the third boundary line is displayed as a draw area, Straight the first boundary Characterized in that it is carried out by displaying a rear.

  According to the swing display method and display chart of the golf club of the present invention, it is advantageous in providing swing characteristics that affect the ball muscles in a simple and easy-to-understand manner.

1 is a block diagram showing a configuration of a golf club setting device 10 of the present embodiment. (A) is a perspective view of an iron-based golf club head 16A to be measured by the golf club selection device 10, (b) is a perspective view of a wood-based golf club head 16B, and (c) is a marker 20a, 20b. 20c and marker feature points 21a, 21b, and 21c. 2 is a perspective view of an irradiation photographing unit 11. FIG. 3 is a plan view of an irradiation photographing unit 11. FIG. It is a top view which shows the modification of the irradiation imaging | photography part 11. FIG. 2 is a block diagram showing a configuration of a computer 14. FIG. 2 is a functional block diagram of a computer 14. FIG. (A) is a schematic diagram showing the time history of marker movement determined from the three-dimensional position coordinates of the marker feature points, and (b) shows the behavior of the golf club head based on the time history of marker movement shown in (a). It is a schematic diagram. 1 is a plan view showing a state in which a golf club head 16 just before hitting a golf ball 2 is viewed in plan. It is a plane schematic diagram explaining the right-and-left approach angle (theta). It is a schematic diagram explaining the face angle φ at the time of impact. FIG. 6 is an explanatory diagram in which the spherical muscles of the golf ball 2 are associated with the left / right approach angle θ and the hitting face angle φ. FIG. 6 is another explanatory diagram in which the spherical muscles of the golf ball 2 are associated with the left / right approach angle θ and the hitting face angle φ. FIG. 6 is still another explanatory diagram in which the ball of the golf ball 2 is associated with the left / right approach angle θ and the hitting face angle φ. FIG. 4 is a schematic diagram for explaining a center of gravity distance L and a center of gravity angle α of a golf club head 16. (A), (b) is a schematic diagram explaining how to obtain | require the gravity center distance L defined with the golf club of this invention. 4 is a flowchart for explaining a selecting operation of the golf club selecting apparatus 10. (A), (b) is an explanatory diagram for explaining a centroid distance _{F GL} and face Progressive Deployment _{F P} on the face. It is explanatory drawing explaining the state which installs the golf club 4 in an address position. (A) is a perspective view of an iron-based golf club 4, (b) is a cross-sectional view of the golf club 4 taken along the line XX ′ shown in (a), and (c) is a grip before mounting. 7 is a cross-sectional view of FIG. (A) is a front view explaining the state which installed the golf club 4 in the normal address position, (b) is a top view. (A), (b), (c) is a figure explaining the relationship between the grip angle β and the orientation of the face surface 1602 of the golf club 4. (A), (b) is explanatory drawing which shows the grip position mark 7C formed in the grip 7. FIG. 4 is a diagram showing a display screen displayed on a display 46 and a display chart created by a printer 48. FIG. 5 is a flowchart for explaining a swing feature display operation and a display chart creation operation by the golf club selection device 10. It is explanatory drawing when there is no face rotation and a spherical muscle becomes a straight tendency. It is explanatory drawing in case there exists face rotation and a spherical muscle tends to hook. It is explanatory drawing in case there exists face rotation and a spherical muscle becomes a straight tendency.

Hereinafter, a golf club selection apparatus to which the golf club swing display method of the present invention is applied and a golf club swing display chart of the present invention will be described.
A schematic configuration of the golf club selection device 10 of the present embodiment will be described.
As shown in FIG. 1, the golf club selection device 10 includes an irradiation photographing unit 11, a control unit 12, and a computer 14.
The irradiation photographing unit 11 photographs the golf club head by stereo photographing from two different directions. In the present embodiment, the irradiation imaging unit 11 constitutes an imaging unit.
The control unit 12 controls the irradiation photographing unit 11 and supplies image data generated by the irradiation photographing unit 11 to the computer 14.
The computer 14 captures data of an image photographed by the irradiation photographing unit 11, performs signal processing, image processing, and operation analysis, classifies golf swings into types, and selects an optimal golf club.
In FIG. 1, reference numeral P indicates a golfer, and reference numeral 4 indicates a golf club.

Next, a golf club head to be measured by the golf club selection device 10 will be described.
FIG. 2A shows an iron-based golf club head 16A to be measured by the golf club selection apparatus 10, and FIG. 2B shows a wood-based golf club head 16B.
In the following, when the iron-based and wood-based golf club heads are expressed without distinction, they are expressed as a golf club 16.
As shown in FIG. 2A, in the iron-based golf club head 16A, markers 20a, 20b, and 20c are provided on the upper end surface of the golf club head 16 that contacts the face surface (striking surface) 1602 and the hosel portion. Yes. Hereinafter, when the markers 20a, 20b, and 20c are not distinguished, they are referred to as the marker 20.
Further, as shown in FIG. 2B, markers 20a, 20b, and 20c are provided at three locations on the top surface that forms a crown portion in contact with the face surface 1602 of the wood-based golf club head 16B.
For example, the markers 20a, 20b, and 20c have a retroreflecting function that reflects the irradiation light of the irradiation light source 22 (to be described later) so that the images of the markers 20a, 20b, and 20c can be always identified when the image is taken by the camera 26 (to be described later). It has a configuration. For example, the markers 20a, 20b, and 20c are obtained by cutting a known retroreflective sheet into a predetermined shape.
The markers 20 are provided at three or more locations on the golf club head, and the arrangement positions are set so that these markers 20 form triangular vertices and do not rest on one straight line.
In the example of FIG. 2A, one marker 20 is provided in the hosel portion so that the three retroreflective markers are not placed on one straight line.

In this embodiment, in order to obtain the position of the marker as will be described later, for example, three or more marker feature points obtained from the marker are used. A marker feature point is a point that characterizes a marker.
In other words, the marker is provided on the surface of the golf club head 16 and has three or more marker feature points.
For example, as shown in FIG. 2 (c), when the markers 20a, 20b, and 20c have a circular shape, the center points of the circular shapes are set as marker feature points 21a to 21c, and the positions are set in the image processing unit 32 described later. Extracted.

In the present invention, in addition to the circular markers 20a, 20b, and 20c of the present embodiment shown in FIG. 2C, for example, a regular polygon such as a regular triangle or a square may be used. it can. In this case, the position of the extracted marker feature point can be the center point (centroid point) of the marker in the case of each regular polygon.
Moreover, the shape of each marker does not need to be the same, The thing of the above-mentioned shape can also be combined freely. Also in this case, each marker feature point of each marker is, for example, the center point (center of gravity) of the marker.
Further, when the marker has, for example, an equilateral triangle shape, each of the three vertexes (intersections of the three sides) of the marker may be used as the marker feature point.
The shape of the marker is not particularly limited as long as it has one or a plurality of marker feature points that characterize the marker and that can be uniquely extracted.

Next, the golf club selection apparatus 10 will be specifically described.
FIG. 3 is a perspective view of the irradiation photographing unit 11, and FIG. 4 is a plan view of the irradiation photographing unit 11.
As shown in FIGS. 3 and 4, the irradiation photographing unit 11 includes an irradiation light source 22, a half mirror 24, a camera 26, a reflection mirror 28, and a base 30. The mirror 24, the camera 26, and the reflection mirror 28 are provided on the base 30.
The irradiation light source 22 irradiates the golf club head 16 as a measurement target.
In the present embodiment, the irradiation light source 22 is composed of a halogen light source, and irradiates continuous light that is temporally continuous.
The irradiation light source 22 is disposed so as to irradiate the marker 20 of the golf club head 16 through the half mirror 24.
The half mirror 24 is a mirror having substantially the same light transmittance and reflectance, and transmits half of the light incident on the reflection surface (boundary surface) of the half mirror 24 and reflects the remaining half of the light.
The half mirror 24 is provided such that, when viewed in plan, the optical path of the light emitted from the irradiation light source 22 forms an incident angle of approximately 45 degrees with respect to the reflection surface.
The camera 26 includes a photographic lens, an imaging element that captures a subject image guided by the photographic lens, a signal processing unit that generates an image signal based on an imaging signal generated by the imaging element, and the like. Yes.
When viewed in plan, the camera 26 passes through a position where the optical axis of the photographing lens intersects the optical path of the irradiation light source 22 and the reflecting surface of the half mirror 24, and the optical axis of the photographing lens is the irradiation light source 22. Is formed so as to form an angle of approximately 90 degrees with the optical path of the light.
The reflection mirror 28 has a total reflection surface that totally reflects light, and has a function of adjusting the reflection direction (angle) and position of the total reflection surface.
The reflection mirror 28 reflects the light irradiated from the irradiation light source 22 and reflected by the half mirror 24 on the total reflection surface to irradiate the markers 20a, 20b, 20c of the golf club head 16, and the markers 20a, 20b, 20c. The reflection direction and position of the total reflection surface are adjusted so that the reflected light from the light is reflected again by the total reflection surface and guided to the camera 26 through the half mirror 24.

Here, as shown in FIG. 4, in the irradiation photographing unit 11, the irradiation light source 22 emits continuous light toward the reflection surface of the half mirror 24.
Half of the light irradiated on the reflective surface of the half mirror 24 is irradiated light that is applied to the markers 20a, 20b, and 20c provided on the golf club head as a measurement target as transmitted light that passes through the position Shm on the reflective surface. It becomes.
Reflected light (hereinafter referred to as marker reflected light 1a) from the markers 20a, 20b, and 20c travels toward the reflecting surface of the half mirror 24.
Here, the marker reflected light 1a travels in the opposite direction to the irradiated light from the irradiation light source 22, and the marker reflected light 1a is reflected light whose optical path matches the irradiation light from the irradiation light source 22. Therefore, the emission angle formed by the light that passes through the reflection surface of the half mirror 24 and is irradiated to the markers 20a, 20b, and 20c with the reflection surface of the half mirror 24, and the marker reflected light 1a is incident on the reflection surface of the half mirror 24. The incident angle is substantially the same.
Thus, the marker reflected light 1a is reflected by the reflecting surface of the half mirror 24 and guided to the photographing lens of the camera 26.

On the other hand, as shown in FIG. 4, the remaining half of the light irradiated on the reflection surface of the half mirror 24 is reflected by the reflection surface of the half mirror 24 and enters the total reflection surface of the reflection mirror 28.
Here, the totally reflected light is irradiated as irradiation light to the markers 20a, 20b, and 20c provided on the golf club head 16 as a measurement target.
The reflected light of the irradiated light from the markers 20a, 20b, and 20c (hereinafter referred to as marker reflected light 1b) is totally reflected from the reflection mirror 28 and overlaps the optical path of the irradiated light that irradiates the markers 20a, 20b, and 20c. It goes to the total reflection surface of the reflection mirror 28.
The marker reflected light 1 b is reflected toward the half mirror 24 on the total reflection surface of the reflection mirror 28.
Here, the reflection angle (irradiation angle) at which the light reflected by the reflecting surface of the half mirror 24 and traveling toward the reflecting mirror 28 forms the reflecting surface of the half mirror 24, and the incident light where the marker reflected light 1b enters the reflecting surface of the half mirror 24. The angles are substantially the same.
Further, the marker reflected light 1 b transmitted through the half mirror 24 enters the photographing lens of the camera 26 together with the marker reflected light 1 a reflected by the half mirror 24.
Therefore, an image of the markers 20a, 20b, and 20c is captured by the camera 26 by two reflected lights from the markers 20a, 20b, and 20c that substantially coincide with the optical paths of the irradiation light irradiated from two different directions.
In the present embodiment, light is irradiated toward the golf club head 16 from two different directions, and an image of the golf club head 16 is taken from two different directions.
In the present invention, the golf club head 16 may be photographed from two or more directions. For example, using a known motion capture system, images of the golf club head 16 are photographed from three different directions by three or more cameras. You can also

In this case, the position and orientation of the reflection mirror 28 are finely adjusted in advance so that the image of the marker reflected light 1b photographed by the camera 26 and the image of the marker reflected light 1a do not overlap.
More specifically, a single image taken by the camera 26 is divided into two in the vertical direction and set as two areas, an upper area and a lower area.
Then, the position and orientation of the reflecting mirror 28 are finely adjusted in advance so that the image by the marker reflected light 1a is taken in the upper area of the image and the image by the marker reflected light 1b is taken in the lower area of the image. Keep it.
In this way, the golf club head 16 is obtained by photographing the images of the markers 20a, 20b, and 20c by the marker reflected light 1a and the images of the markers 20a, 20b, and 20c by the marker reflected light 1b with one camera 26. The images of the markers 20a, 20b, and 20c are taken as stereo images.
Then, with the golf club head 16 moving by the swing, the camera 26 takes images of the markers 20a, 20b, and 20c at intervals of 1/2000 seconds, for example, by multiple exposure.
Thereby, the stereo image of many marker 20a, 20b, 20c is produced | generated by the camera 26 as one image.

  For example, a half prism or various beam splitters can be used as long as it is an optical member that reflects and transmits light incident in both directions on the reflecting surface instead of the half mirror 24. Here, the ratio of the reflectance on the reflecting surface is not particularly limited, but is preferably approximately 1: 1.

Further, the reflection mirror can be configured as follows.
FIG. 5 is a diagram illustrating an example in which the reflection mirrors 28 a and 28 b are arranged in addition to the reflection mirror 28 in the optical path formed by the irradiation photographing unit 11 so that the optical path lengths of the marker reflected lights 1 a and 1 b are aligned.
By providing the reflecting mirrors 28a and 28b in the optical path of the marker reflected light 1a, the optical path from which the marker reflected light 1a reaches the half mirror 24 from the markers 20a, 20b and 20c is lengthened, and the length of the optical path of the marker reflected light 1b is increased. Can be aligned.
That is, by providing the configuration shown in FIG. 5, the optical path length of the marker reflected light 1a becomes longer than that shown in FIG. 4, and the optical path lengths of the marker reflected lights 1a and 1b to the camera 26 can be made substantially uniform.
By making the optical path lengths close to each other in this way, the camera 26 can take an image of each marker by the marker reflected light 1a, 1b in focus.

  Also in this case, when the light irradiated from two different directions is emitted from the reflection surface of the half mirror 24, the respective emission angles are the two reflected lights reflected from the markers 20a, 20b, and 20c (marker reflected light 1a, 1b) substantially coincides with the incident angle of the corresponding reflected light when entering the reflecting surface of the half mirror 24. Therefore, the two reflected light images of the markers 20a, 20b, and 20c provided on the golf club head 16 can be taken with high contrast.

As shown in FIG. 1, the control unit 12 includes a detector 1202 and a buffer memory 1204.
As shown in FIG. 4, the detector 1202 detects whether or not the golf club 16 has passed at a position on the near side of the shooting range of the camera 26 in the movement locus of the golf club 16. .
As the detector 1202, for example, various conventionally known detectors such as a light reflection type detector that detects the presence or absence of an object by detecting reflected light reflected by the object can be used.
The buffer memory 1204 is a storage device that temporarily stores the image data supplied from the camera 26.
When the detector 1202 detects the passage of the golf club 16, the control unit 12 gives a control command to start the shooting operation to the camera 26 and ends the shooting operation when the golf club 16 is out of the shooting range of the camera 26. A control command is given to the camera 26.
The control unit 12 temporarily stores the image data supplied from the camera 26 in the buffer memory 1204, and then supplies the image data to the computer 14.

The computer 14 has a function of measuring the behavior of the golf club head 16 based on the image data supplied from the control unit 12, classifying the swing of the golf club, and selecting the golf club.
Further, the computer 14 displays the swing characteristics of the golf club and creates a display chart showing the characteristics.
FIG. 6 is a block diagram showing the configuration of the computer 14.
The computer 14 includes a CPU 32, a ROM 34, a RAM 36, a hard disk device 38, a disk device 40, a keyboard 42, a mouse 44, a display 46, a printer 48, an input / output interface 50, and the like connected via an interface circuit (not shown) and a bus line. have.
The ROM 34 stores a control program and the like, and the RAM 36 provides a working area.
The hard disk device 38 stores a dedicated program for measuring the behavior of the golf club head 16, classifying the swing, selecting a golf club, and the like.
The disk device 40 records and / or reproduces data on a recording medium such as a CD or a DVD.
The keyboard 42 and the mouse 44 receive an operation input by the operator.
The display 46 displays and outputs data, and the printer 48 prints and outputs data. The display 46 and the printer 48 output data.
In the present embodiment, the display 46 constitutes the display device of the claims.
The input / output interface 50 exchanges data with an external device.

FIG. 7 is a functional block diagram of the computer 14.
Functionally, the computer 14 includes a signal processing unit 52, an image processing unit 54, an analysis unit 56, a classification unit 58, a selection unit 60, an output unit 62, a storage unit 64, an image forming unit 80, an image output unit 82, and the like. It is configured to include.
The signal processing unit 52, the image processing unit 54, the analysis unit 56, the classification unit 58, the selection unit 60, the output unit 62, the image forming unit 80, and the image output unit 82 are executed by the CPU 32 executing the dedicated program. Although realized, these portions may be configured by hardware such as a circuit.

The storage unit 64 is configured by, for example, the hard disk device 38 or the RAM 36, and includes data (CAD data) D1 of the three-dimensional shape model of the golf club head 16, corresponding point position information D2, a classification map D3, and selection information D4. Information including the golf club information D5 is stored in advance.
The information D1 to D5 will be described later.

  For example, only the data values of the portions of the markers 20a, 20b, and 20c can be extracted from the signal processing unit 52 so that the marker feature points 21a, 21b, and 21c can be extracted from the images of the markers 20a, 20b, and 20c in the image. This is a part that performs brightness correction and contrast correction of image data under predetermined processing conditions and further performs gradation processing of a predetermined number of gradations so as to be distinguished from data values of other parts.

The image processing unit 54 is a part that specifies the positions of the marker feature points 21a, 21b, and 21c from the image data of the golf club head 16 during the golf swing, and calculates the behavior of the golf club head 16 using the specified positions. is there.
The image processing unit 54 identifies the marker feature points 21a, 21b, and 21c of the markers 20a, 20b, and 20c and extracts positions in the three-dimensional coordinate system, and 3 of the extracted marker feature points. A calculation unit 54b that calculates time-series data of the position and orientation of the golf club head 16 using the dimensional coordinate position.

The extraction unit 54a identifies image portions of the markers 20a, 20b, and 20c from the image that has been subjected to the gradation processing of a predetermined number of gradations, and extracts the position thereof.
With respect to the images of the markers 20a, 20b, and 20c taken from different directions at the same time, taken by the irradiation imaging unit 11, the position coordinates of the marker feature points 21a, 21b, and 21c are obtained, respectively. Using the position coordinates of the marker feature points 21a, 21b, and 21c, the position coordinates in the three-dimensional coordinate system that defines the space through which the golf club head 16 passes are obtained, and the marker feature points 21a, 21b, and 21c in the three-dimensional coordinate system are obtained. It is configured to extract a position.

Next, the position coordinates of the marker feature points 21a, 21b, and 21c are obtained for the images of the markers 20a, 20b, and 20c in images taken from different directions by the camera 26 at the same time.
The position coordinates in the three-dimensional coordinate system defining the space through which the golf club head 16 passes using the position coordinates of the respective marker feature points 21a, 21b, 21c thus determined as the position coordinates of the markers 20a, 20b, 20c. The coordinates are obtained, and the positions of the marker feature points 21a, 21b, and 21c in the three-dimensional coordinate system are extracted.
Since the shooting direction of the irradiation imaging unit 11 is known, the information representing the two-dimensional position coordinates in the images shot by these irradiation imaging units 11 is obtained, thereby representing a space through which the golf club head 16 passes. The position in the three-dimensional coordinate system (three-dimensional position coordinates) can be obtained.

  When the images of the markers 20a, 20b, and 20c are taken at a predetermined time interval, for example, a time interval of 1/2000 second, each of the images of the markers 20a, 20b, and 20c every 1/2000 second is taken. The time-series data of the three-dimensional position coordinates of the marker feature points (marker center points) 21a, 21b, and 21c can be obtained.

In the present embodiment, the irradiation imaging unit 11 is used to capture images from two directions, and the marker feature points 21a, 21b, 21c to 3 for the images of the markers 20a, 20b, 20c obtained from the respective directions. A dimension position coordinate is obtained.
In the present embodiment, as a configuration in which the marker provided on the surface of the golf club head 16 is continuously photographed from two or more different directions, a stereo image is obtained by one camera 26 as shown in FIG. The case where the irradiation imaging | photography part 11 which images is used was demonstrated.
However, as a configuration for continuously photographing the marker provided on the surface of the golf club head 16 from two or more different directions, various conventionally known configurations such as using two or more cameras can be used. is there.

The calculating unit 54b is a part that calculates the position and orientation of the golf club model as time series data from the three-dimensional position coordinates obtained by the extracting unit 54a.
Specifically, in the storage unit 64, in the three-dimensional coordinate system, the three-dimensional shape model corresponding to the arrangement position of the three-dimensional shape model data (CAD data) D1 of the golf club head 16 and the marker feature points. Corresponding point position information D2 indicating the position of the upper corresponding point is stored.
In other words, the three-dimensional shape model data (CAD data) D1 constitutes a three-dimensional shape model reproducing a golf club head, and the corresponding point position information D2 corresponds to the three-dimensional shape model corresponding to three or more marker feature points. The position of the upper corresponding point is shown.
The calculation unit 54b calls the data D1 and the information D2, and the position coordinates of the corresponding points on the three-dimensional shape model in the three-dimensional coordinate system are the three-dimensional position coordinates of the marker feature points extracted by the extraction unit 54a. The position and orientation of the three-dimensional shape model are calculated so as to match, and the time series data of the position and orientation of the golf club head 16 are calculated with the position and orientation as the position and orientation of the golf club head 16. Is done.

FIG. 8A is a schematic diagram showing a time history of marker movement at a time interval of 1/2000 second, which is determined from the three-dimensional position coordinates of the marker feature points, and FIG. It is a schematic diagram which shows the behavior of a golf club head based on the time history of the movement of the marker shown in FIG. In the figure, reference numeral 2 indicates a golf ball, and an arrow a indicates the moving direction of the golf club head (the launch direction of the golf ball 2). FIG. 8B shows the golf club head viewed from above.
In FIG. 8A, with the predetermined position as the origin, the axis parallel to the launch direction of the golf ball 2 is the X axis, the axis orthogonal to the X axis and parallel to the horizontal plane (the ground) is the Y axis, and the axis is perpendicular to the horizontal plane. An XYZ coordinate system with Z as the Z axis is set in advance.
In FIG. 8A, three plot groups M1, M2 to M10 representing the three markers 20a, 20b, and 20c are three marker feature points extracted from markers photographed at a time interval of 1/2000 second. The positions of 21a, 21b, and 21c are shown.
Further, by associating the golf club head 16 with the three plot groups M1, M2 to M10 representing the markers, and continuously displaying the movement of the golf club head 16 as shown in FIG. 6B. The change in the position of the golf club head 16 and the orientation of the face can be known.
The position of the golf club head 16 represents the position coordinates at the center position of the face surface 1602 as the representative position of the golf club head 16.
The orientation of the face of the golf club head 16 is represented by a normal passing through the center point of the face surface 1602.

The analysis unit 56 uses the time series data of the calculated position and orientation of the golf club head 16, that is, the time series data of the markers 20 a, 20 b, and 20 c, to determine the golf club head 16 immediately before hitting the golf ball 2. The left and right approach angles and the face angle at the time of hitting are obtained.
9 is a plan view showing a state in which the golf club head 16 is viewed in plan just before hitting the golf ball 2, FIG. 10 is a schematic diagram for explaining the definition of the left and right approach angle θ, and FIG. 11 shows the face angle φ at the time of hitting. It is a schematic diagram to explain.
10 and 11, reference numeral 1610 indicates the center position of the face surface 1602 of the golf club head 16.
As shown in FIGS. 9 and 10, a straight line obtained by projecting a target line connecting the center of the golf ball 2 and the target onto the plane is referred to as a reference line L0.
Here, it is assumed that the reference line L0 is parallel to the X axis, and thus the plane is parallel to the X axis and the Y axis and orthogonal to the Z axis.
A straight line obtained by projecting a tangent of the movement locus of the golf club head 16 immediately before hitting the golf ball 2 onto a plane parallel to the horizontal plane is defined as a first straight line L1.
The left / right approach angle θ is an angle formed by the reference line L0 and the first straight line L1.
As shown in FIG. 11, a straight line obtained by projecting a normal line passing through the center point of the face surface 1602 of the golf club head 16 immediately before hitting the golf ball 2 onto the plane is defined as a second straight line L2.
The hit face angle φ is an angle formed by the reference line L0 and the second straight line L2.

That is, the analysis unit 56 obtains the angle formed by the reference line L0 and the first straight line L1 as the left and right approach angle θ from the time series data of the position and orientation of the three-dimensional shape model calculated by the calculation unit 56, The angle formed by the reference line L0 and the second straight line L2 is determined as the face angle φ at impact.
This will be specifically described.
Immediately after the golf ball 2 is hit, the moving speed of the golf club head 16 decreases. Therefore, in the time-series data of the position coordinates representing the movement of the center position 1610 of the face surface 1602 at a certain time interval, the position coordinates immediately before and after the hit. The moving distance of is abruptly shorter than the moving distance at each previous time point.
By utilizing this, as shown in FIG. 10, from the time-series data indicating the position coordinates of the golf club head 16, the position coordinates (center position 1610) of the golf club head 16 immediately before the golf ball 2 is hit, It is possible to specify the previous position coordinate in the series data.
A straight line L1 connecting the two position coordinates is a tangent to the movement locus of the golf club head 16.
Similarly, using the above, as shown in FIG. 11, the face of the golf club head 16 immediately before hitting the golf ball 2 is obtained from time-series data indicating the normal line indicating the direction of the golf club head 16. The normal of the surface 1602 can be specified.
The analysis unit 56 thus identifies the tangent line of the movement path of the golf club head 16 immediately before hitting the golf ball 2 and the normal line of the face surface 1602, and thus the left and right approach angle θ in the above-described procedure. Further, the face angle φ upon hitting is obtained.

Since the head speed of the golf club head 16 is normally 30 to 50 m / sec, the golf club head 16 moves by 15 mm to 25 mm at a time interval δ of 1/2000 second, which is an imaging interval by the camera 26.
Therefore, two time-series data (positional coordinate data) are specified in a range 50 mm before the launching direction of the golf ball 2 along the X-axis direction from the center of the golf ball 2.
Therefore, in the present embodiment, the left / right approach angle θ and the hitting face angle φ are obtained based on time-series data in a range of 50 mm from the center of the golf ball 2.
Note that the shooting interval by the camera 26 is not limited to 1/2000 seconds, and it is only necessary to obtain the left and right approach angle θ and the hitting face angle φ based on the obtained time-series data. The shooting interval is arbitrarily set between 1 / 10,000 seconds and 1/500 seconds.
Further, in the present embodiment, the left and right approach angle θ is a positive (plus) angle on the opposite side of the golfer around the reference line L0, and a negative (minus) angle on the golfer side.
Similarly, with respect to the hitting face angle φ, the opposite side of the golfer around the reference line L0 is a positive (plus) angle, and the golfer side is a negative (minus) angle.

The classification unit 58 specifies which type of a plurality of types of swings of the golf club corresponds to in advance based on the left / right approach angle θ and the hitting face angle φ.
FIG. 12 is an explanatory diagram in which the spherical muscles of the golf ball 2 are associated with the left / right approach angle θ and the hitting face angle φ.
In FIG. 12, the horizontal axis indicates the left and right approach angle θ, and the vertical axis indicates the face angle φ at impact.
In this example, the reference value of the left and right approach angle θ is 0 degree, and the reference value of the hitting face angle φ is 0 degree.
Since the face surface 1602 shows an outside-in tendency as the left and right approach angle θ is negative and the absolute value thereof increases, the launch direction of the golf ball that has been launched is leftward.
As the left and right approach angle θ is a positive value and the absolute value thereof increases, the face surface 1602 shows an inside-out tendency. Therefore, the launch direction of the golf ball that has been launched is the right direction.
A golf ball that is hit as the face angle φ at the time of hitting is negative and increases in absolute value is more likely to be subjected to side spin counterclockwise as viewed from above.
A golf ball that is hit as the face angle φ at the time of hitting is a positive value and its absolute value increases is more likely to be subjected to a side spin in the clockwise direction when viewed from above.
Thus, the combination of the left / right approach angle θ and the hitting face angle φ affects the left / right of the launch direction of the golf ball and the ease with which the side spin is applied, so that the launched golf ball has a tendency to slice and fade. Straight, draw, and hook.
Here, the slicing tendency means that when a right-handed golfer hits a golf ball, the golf ball bends to the right. In the case of a left-handed golfer, the one that turns to the left.
The fade tendency refers to a controlled slicing tendency, in which the landing position of the golf ball launched to the left with respect to the target line returns almost to the target line.
The hook tendency means that when a right-handed golfer hits a golf ball, the golf ball bends to the left. In the case of a left-handed golfer, the golfer turns to the right.
The draw tendency refers to a controlled hook tendency, in which the landing position of the golf ball launched to the right with respect to the target line returns almost to the target line.
Further, the straight tendency means that a hit golf ball goes straight without bending.
As described above, the ball streak (trajectory) of the golf ball 2 varies depending on the behavior of the golf club head 16 immediately before hitting the golf ball 2.
In the present embodiment, a classification map D3 is prepared as information in which the golf club swing type is associated with the combination of the left and right approach angle θ and the hitting face angle φ. Specifically, The classification map D3 is stored in the storage unit 64. Note that where the classification map D3 is provided is arbitrary.

As shown in FIG. 12, the classification map D3 is a plane that is shown on the two-dimensional coordinates with the left-right approach angle θ as the X-coordinate value and the striking face angle φ as the Y-coordinate value. Are divided into a plurality of areas (regions) corresponding to the ball streaks of the golf ball 2 and associated with each other.
In other words, the classification map D3 has an X axis indicating the left and right approach angle θ and a Y axis perpendicular to the X axis and indicating the hit face angle φ, and the intersection of the X axis and the Y axis is the left and right approach angle θ and the hitting time. A plane indicated by a two-dimensional coordinate axis with a face angle φ of zero degrees is divided into a plurality of areas (regions) corresponding to the spherical muscles of the golf ball 2 and associated with each other.
The golf club swing is identified by the classification unit 58 using the classification map D3.
More specifically, as shown in FIG. 12, the classification map D3 corresponds to the combination of the left and right approach angle θ and the hitting face angle φ, the slice area A1, the fade area A2, the straight area A3, and the draw area. Five areas corresponding to the ball of the golf ball 2 such as A4 and hook area A5 are associated with each other.
The slice area A1 is an area where the spherical muscle tends to slice, the fade area A2 is an area where the spherical muscle tends to fade, the straight area A3 is an area where the spherical muscle tends to be straight, and the draw area A4 is a trend where the spherical muscle tends to draw. The hook area A5 is an area where the spherical muscle tends to hook.
In other words, depending on whether the combination of the left and right approach angle θ and the hitting face angle φ corresponds to any of the areas A1 to A5, the golf club swing type is slice type, fade type, straight type, draw type, hook type Specific to any type.
That is, the classification unit 58 corresponds to any of a plurality of types in which the golf swing is stored in the classification map D3 based on the left and right approach angle θ and the hitting face angle φ obtained by the analysis unit 58. To identify.

The slice area A1, fade area A2, straight area A3, draw area A4, and hook area A5 on the classification map D3 are determined as follows.
That is, the golf club is hit with a golf club using a dedicated device, and the right and left approach angle θ of the golf club head and the hitting face angle φ are measured by the selection device according to the present invention. The ball of the golf ball 2 is measured.
Based on the experimental result, each area on the classification map D3 is determined based on the measured left and right approach angle θ, the hitting face angle φ, and the measured spherical muscle.
In the present embodiment, each area on the classification map D3 is divided by a boundary line.

The boundary line includes a first boundary line 90, a second boundary line 92, and a third boundary line 94.
The first boundary line 90 is intended to extend Y as lateral approach angle θ and the striking time of face angles fixed point 96 defined on the axis φ is over negative region or RaTadashi region of positive slope.
In the present embodiment, the fixed point 96 is the origin of the X and Y axes, and is a coordinate point of θ = φ = 0 degrees.
The second boundary line 92 is a first region in which the left and right approach angle θ and the hitting face angle φ are negative, or a region in which the left and right approaching angle θ is negative and the hitting face angle φ is positive. It extends with a smaller inclination than the boundary line 90 and intersects with the fixed point 96.
The third boundary line 94 extends from the fixed point 96 to a region where the left and right approach angle θ and the hitting face angle φ are positive with an inclination smaller than the inclination of the first boundary line 90.
As described above, the fixed point 96 is determined based on the measured left and right approach angle θ, the hitting face angle φ, and the measured spherical muscle.

Accordingly, each of the areas A1 to A5 is divided as follows by the first to third boundary lines 90, 92, and 94.
The slice area A <b> 1 is an area sandwiched between the second boundary line 92 and the straight line portion of the first boundary line 90 that is located in the positive area of the hit face angle φ.
The fade area A <b> 2 is a region sandwiched between the second boundary line 92 and a straight line portion of the first boundary line 90 that is located in the negative region of the hit face angle φ.
The hook area A <b> 5 is an area sandwiched between the straight line portion located in the negative area of the hit face angle φ in the first boundary line 90 and the third boundary line 94.
The draw area A4 is an area sandwiched between the straight line portion of the first boundary line 90 located in the positive area of the hit face angle φ and the third boundary line.
The straight area A3 is a portion of the first boundary line 90.

Further, the position and area of each area on the classification map D3 are not limited to those shown in FIG.
FIG. 13 is another explanatory diagram in which the spherical muscles of the golf ball 2 are associated with the left / right approach angle θ and the hitting face angle φ.
In FIG. 12, the fixed point 96 is a coordinate point with a left / right approach angle θ = 0 ° and a hitting face angle φ = 0 °.
On the other hand, in FIG. 13, the fixed point 96 moves in the positive direction in the Y-axis direction.
As the position of the fixed point 96 changes, the positions and areas of the slice area A1, the fade area A2, the straight area A3, and the draw area A4 on the classification map D3 also change.
For this reason, for example, the following can be considered.
That is, the measurement of the left and right approach angle θ and the hitting face angle φ is made at a position before the position where the golf club head actually hits the golf ball 2.
In general, in the course of swinging the golf club, the face angle of the face surface 1602 of the golf club head 16 changes abruptly from positive to negative immediately before hitting the golf ball 2. That is, face rotation occurs.
Therefore, the hitting face angle φ obtained by the analysis unit 56 and the face angle when the face surface actually hits the golf ball 2 do not exactly coincide with each other, and a deviation occurs.
For example, the hitting face angle φ obtained by the analyzing unit 56 is shifted to the positive side from the face angle at the time of actually hitting the golf ball 2.
Such a deviation occurs due to the selection device 10, and a difference between a golfer, a swing, or a golf club can be ignored.

FIG. 14 is still another explanatory diagram in which the spherical muscles of the golf ball 2 are associated with the left / right approach angle θ and the hitting face angle φ.
In FIG. 14, the fixed point 96 moves in the positive direction in the X-axis direction and the Y-axis direction.
As the position of the fixed point 96 changes, the positions and areas of the slice area A1, the fade area A2, the straight area A3, and the draw area A4 on the classification map D3 also change.
For this reason, for example, the following can be considered.
As described above, the face surface 1602 undergoes face rotation in which the face angle rapidly changes from positive to negative immediately before hitting the golf ball 2.
Also, since this movement (face rotation) continues during the time (about 5 / 10,000 seconds) when the golf ball 2 and the face surface 1602 are in contact with each other at the time of hitting, the left / right approach angle θ is 0 ° and the face angle is Even if the golf ball 2 is hit at 0 °, it is considered that the golf ball 2 jumps slightly to the left with respect to the target line (negative direction), and the golf ball 2 is slightly hooked.
For example, as shown in FIG. 26, when there is no face rotation, the left / right approach angle θ = 0 degrees, and the hitting face angle φ = 0 degrees, the ball muscles tend to be straight.
In addition, as shown in FIG. 27, when there is face rotation, the golf ball 2 is slightly left with respect to the target line even when the left and right approach angle θ = 0 degrees and the hitting face angle φ = 0 degrees. Jumping out (in the negative direction), a slight hook rotation is applied to the golf ball 2, and the ball has a tendency to hook.
In addition, as shown in FIG. 28, when there is face rotation, hitting with the left and right approach angle θ being a positive angle and the hitting face angle φ being a positive angle (slightly opening the face surface 1602 and impacting slightly from the inside ), The ball muscles tend to be straight.
Accordingly, in consideration of such face rotation and the effect of hook rotation applied to the golf ball 2 due to face rotation, the fixed point 96 is divided into a positive part of the X axis and a positive part of the Y axis in the two-dimensional coordinate axis. Will be located in the first quadrant.

In addition, since the position and area of each area on the classification map D3 change due to the cause caused by the selection device 10, the classification map D3 is created according to the selection device 10.
Strictly speaking, the inclinations of the second and third straight lines 92 and 94 slightly change due to the influence of the bulge of the face surface 1602 of the golf club head 16 and the moment of inertia of the golf club head 16.
Therefore, in determining the inclination of the second and third straight lines 92 and 94 in consideration of the influence of the bulge and the moment of inertia, the left and right approach angle θ, the hitting face angle φ, and the ball muscle are determined using various golf clubs. The average value of the slopes of the second and third straight lines 92 and 94 may be obtained based on the result of actual measurement, and the second and third straight lines 92 and 94 may be determined using this average value.
Of course, the left and right approach angle θ and the hitting face angle φ and the ball muscle are measured for each golf club, and the inclinations of the second and third straight lines 92 and 94 are determined from the actual measurement results. The inclinations of the three straight lines 92 and 94 may be properly used.
However, the method using the average value of the former is sufficient to classify the area for knowing the characteristics of the swing, and according to the former method, the classification map D3 is commonly used regardless of the golf club. Therefore, it is advantageous for simplifying the processing for obtaining the swing characteristics.

Further, as shown in FIG. 24, the classification map D3 includes a left and right approach angle θ obtained by the analysis unit 58 and a hitting face angle φ when a specific golfer swings a golf club and hits a golf ball. A portion where the measurement points are concentrated and distributed is stored as a first comparison area.
Here, the measurement point refers to a coordinate point indicating the value of the left and right approach angle θ and the value of the hitting face angle φ measured when the golfer hits the golf ball with the golf club.
That is, using the selection device 10, the distribution of measurement points is obtained by actually measuring the left and right approach angle θ and the hitting face angle φ by a specific professional golfer, and the distribution is used as a first comparison area as a classification map D3. Store.
The specific golfer is a golfer classified based on a specific condition, and includes, for example, those listed below.
1) Men's professional golfers and women's professional golfers who play an active role in golf tournaments targeted by general amateur golfers 2) Men's amateur golfers and women's amateur golfers classified by handicap 3) Men's amateur golfers and women's amateurs classified by age Golfers Note that specific golfers are not limited to these, and golfers classified according to various conditions are defined as specific golfers, and the first comparison area is configured corresponding to such specific golfers. Of course, you can do it.
In this embodiment, the case where a specific golfer is a male professional golfer and a female professional golfer is illustrated, and the first comparison area is a male professional golfer area 100 corresponding to a male professional golfer and a female professional golfer. And a corresponding female professional golfer area 102.
In the classification map D3, the portion where the measurement points obtained by the analysis unit 58 are concentrated and distributed when the golf club is swung by hitting a golf club with an ideal swing using a dedicated device is the second portion. It may be stored as a comparison area.
That is, using the selection device 10, the measurement points of the dedicated device are actually measured to obtain the distribution of the measurement points, and the distribution is stored as the second comparison area as the classification map D3.

The selection unit 60 selects an optimal golf club according to the type specified by the classification unit 58.
In the present embodiment, selection information D4 in which a swing type of a golf club and a golf club optimum for the type are associated is prepared in advance. Specifically, the selection information D4 is stored in the storage unit 64. ing. Note that where the selection information D4 is stored is arbitrary.
The selection information D4 is information in which the swing type of the golf club is associated with the golf club most suitable for the type.
The format of the selection information D4 is arbitrary, for example, including a data table in which a golf club swing type and a golf club optimum for the type are associated with each other.
That is, the golf club most suitable for the type is a golf club that is advantageous in correcting the spherical muscle when the golf ball 2 is hit with the type of swing.
The selection unit 60 selects an optimal golf club from the selection information D4 based on the golf club swing type specified by the classification unit 58.

As the golf club selected by the selection unit 60 (in other words, the golf club associated with the swing type of the golf club in the selection information D4), it is preferable to set various centroid distances and centroid angles of the golf club head. What is obtained by doing is used.
That is, the optimum golf club head for each type is configured so that at least one of the center-of-gravity distance and the center-of-gravity angle is different.

As shown in FIG. 15, the center of gravity distance of the golf club head is the shortest straight line from the center of gravity G of the golf club head 16 to the center axis S (shaft axis) of the golf club shaft or an extension of the center axis S. Is the distance L of the shortest straight line.
The center-of-gravity angle means that the golf club head 16 is placed on the horizontal plane according to the set lie angle, and the shortest straight line and the central axis S of the golf club shaft or an extension line of the central axis S are set from the vertical direction to the horizontal plane. An angle α formed between the shortest straight line and the central axis S of the golf club shaft or an extension line of the central axis S when projected toward the front. That is, the barycenter angle α is an angle representing the direction of the shortest straight line.
Then, by changing the value of the center of gravity distance L between large and small according to each type, it is possible to make it suitable for each type.
In other words, the type corresponding to the slice area selects the golf club head 16 having a small center of gravity distance L (short), and the type corresponding to the hook area selects the golf club head 16 having a large center of gravity distance L (long).
In order to clarify the range of difference in the center of gravity distance L between the golf club heads 16, the difference in center of gravity distance L between the golf club heads 16 is preferably 3 mm to 10 mm.
Further, by changing the value of the barycentric angle α to large or small according to each type, it is possible to make it suitable for each type.
In other words, the type corresponding to the slice area selects the golf club head 16 having a large center of gravity angle α, and the type corresponding to the hook area selects the golf club head 16 having a small center of gravity angle α.

The above-described center-of-gravity distance L can be obtained as follows, for example.
As shown in FIG. 16A, the measurement is performed by a seesaw type balance 70 that can swing in the direction of an arrow U around a fulcrum 71.
The balance 70 has a shaft pin 72 having a fit with no gap with respect to the hosel hole of the golf club head 16 and is balanced so that the arm 73 is horizontal when the golf club head is not attached. .
As shown in FIG. 15 (b), the center of gravity distance L from the golf club shaft axis of the center of gravity G of the golf club head 16 is measured by mounting and fixing a golf club head having a mass W on the shaft pin 72. Then, a precision balance is placed at a predetermined position (L ′) so that the arm 73 is horizontally balanced, and the load when the balance 70 is suspended is measured.
Then, the direction of the golf club head mounted on the shaft pin 72 is adjusted so that this load is maximized, and the load W ′ when it is maximized is obtained. Based on this load W ′, from the balance formula L = (W ′ × L ′) / W is calculated. This calculated value is the centroid distance L.

As described above, the case where the wood-based golf club head optimum for each type is prepared and selected by adjusting the center-of-gravity distance L and the center-of-gravity angle α has been described, but instead of the center-of-gravity distance L, the center-of-gravity distance F on the face surface. _GL can also be used.

Here, “the center-of-gravity distance F _GL on the face surface” will be described.
As shown in FIGS. 18A and 18B, “the center-of-gravity distance F _GL on the face surface” is a point g where a perpendicular line L1 perpendicular to the face surface passing through the center of gravity G intersects the face surface 1602 and the golf club shaft. Is the shortest distance between the face axis 1602 or a line obtained by projecting the extension line of the center axis S onto the face surface 1602 or a surface obtained by extending the face surface 1602.
The point g can be detected using a conventionally known center-of-gravity measuring instrument. For example, the method described in paragraphs 0028 to 0030 of Japanese Patent No. 4233886 can be used. In short, the point g can be detected by any method as long as the perpendicular L1 perpendicular to the face surface passing through the center of gravity G intersects the face surface 1602.
Then, the value of the centroid distance F _GL on the face depending on the type of the large, by changing the small, may be suitable to each type of the.
In other words, the type corresponding to the slice area is small centroid distance F _GL on the face surface (short) selects a golf club head 16, the type corresponding to the hook area centroid distance F _GL on the face surface is large (long ) A golf club head 16 is selected.

  Furthermore, as described in JP 2006-247045 A, when the grip angle β in the golf club is determined, the grip angle β can be used instead of the barycentric angle α.

Here, “grip angle β” will be described.
FIG. 20A is a perspective view of an iron-based golf club 4.
The golf club 4 includes a golf club shaft 5, a golf club head 6 attached to the front end portion of the golf club shaft 5, and a grip 7 attached to the rear end portion of the golf club shaft 5.
FIG. 20B is a cross-sectional view of the golf club 4 taken along the line XX ′ shown in FIG.
A grip 7 is provided so as to surround the golf club shaft 5, and a partially protruding protrusion is provided on a part of the outer periphery of the grip 7.
This protrusion is provided at the same circumferential position in the longitudinal direction of the golf club shaft 5 to form a back line 7A.
As shown in FIG. 20 (c), the back line 7 A has a flat portion 7 B formed on a part of the inner peripheral surface of the grip 7 before mounting. By mounting the golf club shaft 5, the back line 7 A is It is formed in a convex shape.
The back line 7 </ b> A is a specific part for specifying the mounting direction when the grip 7 is mounted on the golf club shaft 5.
The grip angle β is information indicating the mounting direction of the specific part (back line 7A) with respect to the direction of the face surface 1602 of the golf club head 16.
The specific portion is not limited to the back line 7A, and may be a visually recognizable index formed on the surface of the golf club shaft 5 or the surface of the grip 7.
For example, as shown in FIGS. 23 (a) and 23 (b), a grip position mark 7 </ b> C is formed on the surface of the grip 7 for displaying a grip position where the thumbs of the left and right hands are applied when the grip 7 is gripped. In this case, the grip position mark 7C may be a specific part.

FIG. 21A is a front view for explaining a state in which the golf club 4 is installed at a normal address position, and FIG. 21B is a plan view.
FIGS. 22A, 22 </ b> B, and 22 </ b> C are views for explaining the relationship between the grip angle β and the orientation of the face surface 1602 of the golf club 4.
More specifically, as shown in FIGS. 21A and 21B, the grip angle β is set by placing the golf club 4 on a horizontal reference plane B (horizontal plane) according to the lie angle, and the grip 7 and the golf club. On the cutting plane when the shaft 5 is cut perpendicularly to the central axis S, as shown in FIGS. 22 (a), (b) and (c), the circumference around the golf club shaft 5 provided with the back line 7A. When a straight line L2 passing from the position through the central axis S and a projection line H1 when a horizontal line (a straight line parallel to the score line) on the face surface 1602 of the golf club head 16 is projected onto the cutting plane are defined, An angle formed by the direction of L2 with respect to the direction of the projection line H1.
Therefore, when the straight line L2 and the projection line H1 are parallel, the grip angle β is 0 degree.

The horizontal line on the face surface 1602 of the golf club head 16 refers to a straight line on the face surface 1602 parallel to the reference surface B in a state where the golf club 4 is installed at a normal address position (installed according to the lie angle).
This horizontal line is generally substituted by a score line 1630 or a straight line parallel to the score line 1630.
The score line 1630 is set to indicate a reference for the face surface 1602.
If the score line 1630 is not linear, for example, a line parallel to the reference plane B is marked on the face surface 1602 on the face surface 1602 in a state where the score line 1630 is installed at a normal address position. It can be a horizontal line.
Here, setting the golf club 4 at the normal address position means that the golf club head 16 is set at the lie angle and the center axis S and the reading are as shown in FIGS. 21 (a) and 21 (b). This means that the edge 1620 is installed so as to be parallel to each other and so as to be parallel to the score line 15.
Installation according to the lie angle is as described in paragraph 0043.
Further, when the score line 1630 is not linear, the fact that the central axis S and the leading edge 1620 are parallel to each other indicates a state in which the face angle is 0 degree.

In the present embodiment, the grip angle β is defined as a negative (minus) angle when the face surface 1602 closes around 0 degrees, and a positive (plus) angle when the face surface 1602 opens.
By changing the sign of the grip angle β and the magnitude of the absolute value according to each type, the grip angle β can be made suitable for each type.
In other words, the type corresponding to the slice area selects the golf club head 16 having a negative grip angle β (the face surface 1602 is closed), and the type corresponding to the hook area has a positive grip angle β (the face surface 1602 is Open (open) golf club head 16 is selected.
When the golfer grips the golf club, the golfer grips the golf club with reference to the mark or indication displayed on the grip. Therefore, by changing the grip angle β, the golf club head face direction is changed in the address state. The direction of movement of the face surface immediately before hitting the golf ball changes. For this reason, the optimal golf club can be provided according to each said type.

In addition, as the golf club selected by the selection unit 60, a golf club obtained by setting various face progressions of the golf club head is preferably used.
As shown in FIG. 18, the face progression F _P, the distance from the center axis S to the most advanced position C of the golf club head 16. That is, face progression F _P is the distance from the central axis S to the leading edge is a place where the face surface 1602 and the sole portion 1604 is in contact.
By changing the magnitude of the face progression F _P depending on the type of the can to be suitable for each type of the.
In other words, the type corresponding to the slice area selected a golf club head 16 face progression F _P is small, the type corresponding to the hook area to select a golf club head 16 face progression F _P is large.
The golf club head 16 having a small face progression is called a gooseneck or offset.

In addition, when the golf club selected by the selection unit 60 is a wood system, a golf club that is obtained by setting various face angles of the golf club head is preferably used.
In the present embodiment, the face angle is defined as a negative (minus) angle in the direction in which the face surface 1602 closes around 0 degree, and a positive (plus) angle in the direction in which the face surface 1602 opens.
That is, it is possible to make the golf club head suitable for each type by changing the sign of the face angle of the golf club head and the magnitude of the absolute value according to each type.
In other words, the type corresponding to the slice area selects the golf club head 16 having a negative face angle (face surface 1602 is closed), and the type corresponding to the hook area is a positive face angle (face surface 1602 is open). The golf club head 16) is selected.
In other words, the type corresponding to the slice area may be selected as the golf club head 16 having a hook face, and the type corresponding to the hook area may be selected as the golf club head 16 having a slice face.

In addition, when the golf club selected by the selection unit 60 is an iron type, a golf club obtained by setting various lie angles of the golf club head is preferably used.
In other words, the type corresponding to the slice area selects the golf club head 16 having an upright lie angle, and the type corresponding to the hook area selects the golf club head 16 having a flat lie angle.

  Also, for these golf clubs, information indicating that the golf club is optimal for each of the above-mentioned types, that is, information on the type to be classified, is presented on a display medium such as a sticker or tag attached to the golf club. It is preferable. A golfer can also select a golf club suitable for his / her golf swing from a large number of golf clubs using the display medium as a guide.

The output unit 62 displays information for specifying the golf club selected by the selection unit 60, that is, the golf club information D5 on the screen by the display 46, or prints it on a print medium by the printer 48 and outputs it. Alternatively, the golf club information D5 is output to a disk-shaped recording medium via the disk device 40, or is output to an external device via the input / output interface 50.
The golf club information D5 is stored in advance in the storage unit 64, and the output unit 62 reads out the golf club information D5 corresponding to the golf club from the storage unit 64 based on the golf club selected by the selection unit 60. Output. It is arbitrary where the golf club information D5 is stored.
The golf club information includes various information such as a golf club product name, product number, various specifications, an external view, and a photograph.

The image forming unit 80 displays on the basis of the data of the classification map D3 read from the storage unit 64 and the data of the measurement points that are the data of the left and right approach angles θ and the hitting face angle φ supplied from the analysis unit 56. Image data for printing and image data for printer output are formed.
The measurement point may be one data obtained by one measurement or may be an average value of N data obtained by N measurements (N is a natural number of 2 or more). Good.
If the measurement point is an average value of N pieces of data, it is advantageous in suppressing variation of the measurement point.
Note that such calculation of the average value may be performed by the analysis unit 56 or the image forming unit 80, and where it is performed is arbitrary.

The image output unit 82 supplies the display display image data supplied from the image forming unit 80 to the display 46 to display the swing characteristics of the golf club on the display screen of the display 46.
The image output unit 82 also supplies the printer output image data supplied from the image forming unit 80 to the printer 48, thereby printing the swing characteristics of the golf club on paper as a recording medium. Create a display chart for.

Here, the display screen displayed on the display 46 by the image forming unit 80 and the image output unit 82 and the display chart created by the printer 48 will be described in detail.
FIG. 24 is a diagram showing a display screen displayed on the display 46 and a display chart created by the printer 48.
The display screen created by the display screen of the display 46 and the printer 48 includes an X axis indicating the left and right approach angle θ, a two-dimensional coordinate axis orthogonal to the X axis and a Y axis indicating the hit face angle φ, Through the third boundary lines 90, 92, and 94, various areas A1 through A5, and measurement points are displayed.

Next, the operation of the golf club selecting apparatus 10 will be described.
The selection device 10 performs an operation of selecting a golf club, an operation of displaying the swing characteristics of the golf club by the golfer on a display, and an operation of creating a display chart showing the swing characteristics.
Below, for convenience of explanation, the golf club selection operation, the swing feature display operation, and the display chart creation operation will be described separately.
First, a golf club selection operation will be described.
FIG. 17 is a flowchart for explaining the selecting operation of the golf club selecting apparatus 10.
When the golfer swings the golf club and hits the golf ball 2 placed on the tee, the control unit 12 causes the detector 1202 to detect the golf club head 16, thereby causing the camera 26 to perform a shooting operation and image data. Are stored in the buffer memory 1204 (step S10: photographing step).

  The image data is supplied to the image processing unit 54 via the signal processing unit 52, and each marker feature point is extracted from the image data by the extraction unit 54a (step S12: extraction step).

  The calculation unit 54b is a three-dimensional shape data D1 (three-dimensional shape model) that reproduces the golf club head 16 stored in the storage unit 64, and a three-dimensional shape model corresponding to three or more marker feature points. Based on the corresponding point position information D2 indicating the position of the corresponding point, the position of the corresponding point matches the position in the three-dimensional coordinate system of the three or more marker feature points extracted by the extraction unit 54a. By determining the position and orientation of the three-dimensional shape model, time-series data of the position and orientation of the three-dimensional shape model that reproduces the behavior of the golf club head 16 is calculated (step S14: calculation step).

Next, the analysis unit 56 obtains the left and right approach angle θ and the hitting face angle φ from the time-series data of the position and orientation of the three-dimensional shape model (step S16: analysis step).
Next, the classification unit 58 uses the classification map D3 to identify which type of golf club swing is a predetermined type based on the left / right approach angle θ and the hitting face angle φ. (Step S18: classification step).

  Next, the selection unit 60 selects a golf club corresponding to the specified type using the selection information D4 (step S20: selection step).

Next, the output unit 62 reads out and outputs the golf club information D5 corresponding to the selected golf club from the storage unit 64 (step S22: output step).
Accordingly, a golf club suitable for the golfer's swing type is selected.

Therefore, since the type of golf swing is classified based on the left and right approach angle θ and the hitting face angle φ of the golf club head immediately before hitting the golf ball, the golf ball that affects the ball muscles such as hooks and slices of the golf ball This is advantageous for more accurately classifying the type of swing.
And since a golf club is selected based on the classification result, it is advantageous in selecting an optimum golf club for a golfer.

FIG. 25 is a flowchart for explaining the swing feature display operation and display chart creation operation by the golf club selection apparatus 10.
Steps S30, S32, S34, and S36 are the same as steps S10, S12, S14, and S16 in FIG.

  In step S38, the image forming unit 80 converts the data of the classification map D3 read from the storage unit 64 and the data of the measurement points supplied from the analysis unit 56 (data of the left and right approach angle θ and the hitting face angle φ). Based on this, image data for display display is formed and image data for printer output is formed (step S38).

The image output unit 82 displays the two-dimensional coordinate axes including the X axis and the Y axis on the display screen of the display 46 based on the display display image data supplied from the image forming unit 80 (step S40: coordinate axis display). Step).
Next, the image output unit 82 displays the first, second, and third boundary lines 90, 92, and 94 on the display screen of the display 46 based on the display display image data supplied from the image forming unit 80. Display (step S42: boundary line display step).

  Next, the image output unit 82 displays the slice area A1, the fade area A2, the straight area A3, the draw area A4, the hook on the display screen of the display 46 based on the display display image data supplied from the image forming unit 80. Area A5 is displayed (step S44: various area display step). In other words, the image output unit 82 displays a plurality of areas A1 to A5 that are divided according to the tendency of the spherical muscles.

Next, the image output unit 82 displays the measurement points on the display screen of the display 46 based on the display display image data supplied from the image forming unit 80 (step S46: measurement point display step).
As a result, the swing feature is displayed on the display screen of the display 46 as shown in FIG.
FIG. 24 shows, for example, a case where measurement is performed three times using two golf clubs A and B, a measurement point a is a measurement point when using the golf club A, and a measurement point b is golf The measurement points when Club B is used are shown.
In this case, it can be seen that there is a difference in swing between the golf clubs A and B.

Next, the image output unit 82 supplies the printer output image data supplied from the image forming unit 80 to the printer 48, thereby printing the swing characteristics of the golf club on a recording medium, thereby displaying a swing display chart. Create (step S48).
As a result, as shown in FIG. 24, a display chart showing the characteristics of the swing is output.

According to the swing display method of the golf club of the present embodiment, the following operational effects are achieved.
When the golfer actually swings on the display screen of the display 46, a two-dimensional coordinate axis indicating the left and right approach angle θ and the hitting face angle φ, a plurality of areas demarcated according to the tendency of the ball of the golf ball 2, and the golfer actually swings Measurement points for measuring the behavior of the golf club head are displayed.
Therefore, it is advantageous in providing a swing feature that affects the spherical muscles such as slices and hooks in a simple and easy-to-understand manner based on which of the plurality of areas the measurement point is located.

In particular, in the present embodiment, slice area A1, fade area A2, straight area A3, draw area A4, and hook area A5 are displayed as a plurality of areas. Based on the area where the measurement point is located. It is even more advantageous in providing swing features that affect the ball muscles such as slices and hooks in a simple and easy-to-understand manner.
In addition, the swing of how to correct each of the left and right approach angles θ and the hitting face angle φ by grasping the deviation of the measurement points with respect to the fade area A2 and the draw area A4 which are ideal swings. This is advantageous in understanding the improvements.
In particular, it is possible to easily provide the golfer with the results of practice at a golf driving range or the like, which is advantageous in effectively carrying out the practice of the golfer.
Further, if measurement is performed using a plurality of types of golf clubs at a golf shop or the like, the characteristics of the golf clubs can be specifically compared. Therefore, when a golfer purchases a golf club, the golf club can be accurately evaluated, which is advantageous in promoting sales.
Alternatively, when using a conventional product and a new product to measure when a new product of a golf club is publicized, it is possible to show the improvements of the new product compared to the conventional product, which is advantageous in increasing the effectiveness of the publicity. It becomes.

In the present embodiment, an area corresponding to a specific golfer, for example, a male professional golfer area 100 and a female professional golfer area 102 are displayed as the first comparison area.
Therefore, the golfer is advantageous in knowing the difference between the swing of the golf player and the swing of the specific golfer as a specific numerical difference between the left and right approach angle θ and the hitting face angle φ.
Further, when the golf ball is swung by hitting an ideal swing as the second comparison area, a portion where the measurement points are concentrated and distributed is displayed.
Therefore, it is advantageous for the golfer to know the difference between his / her swing and the ideal swing as a specific numerical difference between the left / right approach angle θ and the hitting face angle φ.

Moreover, according to the display chart of the swing of the golf club of this Embodiment, the following effects are show | played.
Since the display chart has a two-dimensional coordinate axis indicating the left and right approach angle θ and the hitting face angle φ, and an area indicating the ball muscle of the golf ball 2, the left and right approaching angle θ and the hitting face angle φ, The relationship with the area can be easily understood, that is, it is advantageous to easily understand the characteristics of the swing.

In particular, in the present embodiment, the plurality of areas include a slice area A1, a fade area A2, a straight area A3, a draw area A4, and a hook area A5. The relationship with the area can be more easily understood, that is, it is more advantageous to easily understand the characteristics of the swing.
Further, since it can be carried or stored as a medium, it is more advantageous in increasing the value of services provided to golfers.
In addition, by measuring the behavior of the golf club head when the golfer actually swings and displaying the measurement points on the display chart, the swing characteristics can be easily understood based on the area where the measurement points are displayed. Is advantageous.
In addition, when the area corresponding to a specific golfer, for example, the male professional golfer area 100 and the female professional golfer area 102, are displayed as the first comparison area, the golfer can compare his own swing with the swing of the specific golfer. It is advantageous to know the difference as a specific numerical difference between the left and right approach angle θ and the hitting face angle φ.
In addition, when a golf club is swung by an ideal swing using a dedicated device as the second comparison area and a golf ball is hit, a portion where the measurement points are concentrated and distributed is displayed. It is advantageous to know the difference between the own swing and the ideal swing as a specific difference between the left and right approach angles θ and the hitting face angle φ.
A display chart having a two-dimensional coordinate axis and an area may be prepared in advance, and the measurement points may be printed later by the printer 48.
This is advantageous in reducing the printing time.

In the present embodiment, the case where the area corresponding to the ball of the golf ball 2 is divided into five areas such as a slice area A1, a fade area A2, a straight area A3, a draw area A4, and a hook area A5 has been described. .
However, for example, if it should be classified as either flying straight, turning right, or turning left, it may be divided into three areas such as a slice area, a straight area, and a hook area.
In addition, it is difficult to think that it will fly straight in the first place, and if it should be classified as either turning right or turning left, it may be divided into two areas such as a slice area and a hook area.
That is, each area can be appropriately set according to the concept of those skilled in the art.
Also, the range of each area can be appropriately set according to the concept of those skilled in the art, for example, by increasing the tolerance of bending and increasing the range of the straight area.

  2 ... Golf ball, 4 ... Golf club, 10 ... Golf club selection device, 16 ... Golf club head, 1602 ... Face surface, 90 ... First boundary line, 92 ... Second boundary Line 94 ... Third boundary line 96 ... Fixed point 100 ... Men's professional golfer area, 102 ... Women's professional golfer area, L0 ... Base line, L1 ... First straight line, L2 ... First 2 straight line, θ …… Left and right approach angle, φ …… Face face angle, A1 …… Slice area, A2 …… Fade area, A3 …… Straight area, A4 …… Draw area, A5 …… Hook area.

Claims (4)

A golf club swing display method for displaying on a display device swing characteristics measured based on the behavior of a golf club head immediately before the golf club head of a golf club swung by a golfer hits a golf ball,
A reference line obtained by projecting a target line connecting the center of the golf ball and the target onto a plane parallel to a horizontal plane, and a tangent to the movement trajectory of the golf club head immediately before hitting the golf ball are projected onto the plane. The angle formed by the straight line is the left and right approach angle,
The positive and negative of the left and right approach angle is a positive angle on the opposite side of the golfer around the reference line, a negative angle on the golfer side,
The angle formed between the reference line and the second straight line projected on the plane from the normal line passing through the center point of the face surface of the golf club head immediately before hitting the golf ball is the face angle at the time of hitting,
The positive / negative of the face angle at the time of hitting is a positive angle on the opposite side of the golfer around the reference line, and a negative angle on the golfer side,
On the display screen of the display device, an X axis indicating the left and right approach angle, and a Y axis perpendicular to the X axis and indicating the face angle at the time of hitting, the intersection of the X axis and the Y axis are the left and right approach angles and the A coordinate axis display step for displaying a two-dimensional coordinate axis with a face angle of zero when hitting;
Various area display steps for displaying a plurality of areas demarcated according to the tendency of the bulb muscles on the display screen;
A measurement point display step for displaying, on the display screen, a coordinate point indicating the value of the left and right approach angle measured when the golfer hits a golf ball using a golf club and the value of the face angle at the time of hitting as a measurement point. Including
Before the various area display steps are performed,
On the display screen, the left and right approach angles and the hitting face angle pass through a fixed point defined in a first quadrant defined by a positive part of the X axis and a positive part of the Y axis in the two-dimensional coordinate axis. A first boundary line extending from the negative region to the positive region with a positive slope;
An area where the left and right approach angle and the face angle at the time of hitting are negative or an area where the left and right approach angle is negative and the area at which the hit face angle is positive is included in this area is smaller than the first boundary line. A second boundary line extending at the point and intersecting the fixed point;
A boundary line display step is performed for displaying the left and right approach angles and the third boundary line extending in the positive region of the hitting face angle from the fixed point with an inclination smaller than the inclination of the first boundary line. ,
The display of a plurality of areas divided according to the tendency of the ball muscles by the various area display steps,
A region sandwiched between the straight line portion located in the positive area of the face angle at the time of hitting and the second boundary line in the first boundary line is displayed as a slice area,
A straight line portion located in the negative area of the face angle at the time of hitting in the first boundary line and a region sandwiched between the second boundary lines are displayed as a fade area,
Displaying a region sandwiched between the straight line portion of the first boundary line located in the negative region of the face angle at impact and the third boundary line as a hook area;
A straight line portion located in a positive area of the face angle at the time of hitting in the first boundary line and a region sandwiched between the third boundary lines are displayed as a draw area,
It is performed by displaying the first boundary line as a straight area.
A method for displaying a swing of a golf club. The fixed point is determined based on the value of the left and right approach angle measured when the golf ball is hit using a golf club, the measured value of the face angle value at the time of hitting, and the measured golf ball ball line. The
The golf club swing display method according to claim 1 , wherein the golf club swing is displayed. A first comparison area display step of displaying, on the display screen, a portion where the measurement points are concentrated and distributed as a first comparison area when a specific golfer swings a golf club and hits a golf ball; Including,
The golf club swing display method according to claim 1, wherein the golf club swing is displayed. A second comparison area display step of displaying, on the display screen, a portion where the measurement points are concentrated and distributed as a second comparison area when the golf ball is swung by an ideal swing and hits a golf ball. In addition,
The golf club swing display method according to claim 1, wherein the golf club swing is displayed.

Images