Method for predicting a golfer's ball striking performance

Information

  • Patent Grant
  • 6821209
  • Patent Number
    6,821,209
  • Date Filed
    Thursday, July 31, 2003
    21 years ago
  • Date Issued
    Tuesday, November 23, 2004
    20 years ago
Abstract
A method for a predicting golfer's performance is disclosed herein. The method inputs the pre-impact swing properties of a golfer, a plurality of mass properties of a first golf club, and a plurality of mass properties of a first golf ball into a rigid body code. Ball launch parameters are generated from the rigid body. The ball launch parameters, a plurality of atmospheric conditions and lift and drag properties of the golf ball are inputted into a trajectory code. This trajectory code is used to predict the performance of a golf ball if struck by the golfer with the golf club under the atmospheric conditions. The method can then predict the performance of the golf ball if struck by the golfer with a different golf club. The method and system of the present invention predict the performance of the golf ball without the golfer actually striking the golf ball.
Description




STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT




Not Applicable




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to a method for predicting a golfer's ball striking performance for a multitude of golf clubs and golf balls. More specifically, the present invention relates to a method for predicting a golfer's ball striking performance for a multitude of golf clubs and golf balls without the golfer actually using the multitude of golf clubs and golf balls.




2. Description of the Related Art




For over twenty-five years, high speed camera technology has been used for gathering information on a golfer's swing. The information has varied from simple club head speed to the spin of the golf ball after impact with a certain golf club. Over the years, this information has fostered numerous improvements in golf clubs and golf balls, and assisted golfers in choosing golf clubs and golf balls that improve their game. Additionally, systems incorporating such high speed camera technology have been used in teaching golfers how to improve their swing when using a given golf club.




An example of such a system is U.S. Pat. No. 4,063,259 to Lynch et al., for a Method Of Matching Golfer With Golf Ball, Golf Club, Or Style Of Play, which was filed in 1975. Lynch discloses a system that provides golf ball launch measurements through use of a shuttered camera that is activated when a club head breaks a beam of light that activates the flashing of a light source to provide stop action of the club head and golf ball on a camera film. The golf ball launch measurements retrieved by the Lynch system include initial velocity, initial spin velocity and launch angle.




Another example is U.S. Pat. No. 4,136,387 to Sullivan, et al., for a Golf Club Impact And Golf Ball Launching Monitoring System, which was filed in 1977. Sullivan discloses a system that not only provides golf ball launch measurements, it also provides measurements on the golf club.




Yet another example is a family of patent to Gobush et al., U.S. Pat. No. 5,471,383 filed on Sep. 30, 1994; U.S. Pat. Nos. 5,501,463 filed on Feb. 24, 1994; U.S. Pat. No. 5,575,719 filed on Aug. 1, 1995; and 5,803,823 filed on Nov. 18, 1996. This family of patents discloses a system that has two cameras angled toward each other, a golf ball with reflective markers, a golf club with reflective markers thereon and a computer. The system allows for measurement of the golf club or golf ball separately, based on the plotting of points.




Yet another example is U.S. Pat. No. 6,042,483 for a Method Of Measuring Motion Of A Golf Ball. The patent discloses a system that uses three cameras, an optical sensor means, and strobes to obtain golf club and golf ball information.




However, these disclosures fail to provide a system or method that will predict a golfer's performance with a specific golf club or golf ball in different atmospheric conditions, without having the golfer physically strike the specific golf ball with the specific golf club. More specifically, if a golfer wanted to know what his ball striking performance would be like when he hit a CALLAWAY GOLF® RULE 35® SOFTFEEL™ golf ball with a ten degrees CALLAWAY GOLF® BIG BERTHA® ERC® II forged titanium driver, the prior disclosures would require that the golfer actually strike the CALLAWAY GOLF® RULE 35® SOFTFEEL™ golf ball with a ten degrees CALLAWAY GOLF® BIG BERTHA® ERC® II forged titanium driver. Using the prior disclosures, if the golfer wanted to compare his or her ball striking performance for ten, twenty or thirty drivers with one specific golf ball, then the golfer would have use each of the drivers at least once. This information would only apply to the specific golf ball that was used by the golfer to test the multitude of drivers. Now if the golfer wanted to find the best driver and golf ball match, the prior disclosures would require using each driver with each golf ball. Further, if the golfer wanted the best driver/golf ball match in a multitude of atmospheric conditions (e.g. hot and humid, cool and dry, sunny and windy, . . . etc.) the prior disclosures would require that the golfer test each driver with each golf ball under each specific atmospheric condition.




Thus, the prior disclosures fail to disclose a system and method that allow for predicting a golfer's ball striking performance for a multitude of golf clubs and golf balls without the golfer actually using the multitude of golf clubs and golf balls.




BRIEF SUMMARY OF THE INVENTION




It is thus an object of the present invention to provide a system and method that allow for predicting a golfer's ball striking performance for a multitude of golf clubs and golf balls without the golfer actually using the multitude of golf clubs and golf balls.











BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS





FIG. 1

is a flow chart of the general method of the present invention.





FIG. 1A

is a flow chart illustrating the inputs for the golf club head properties.





FIG. 1B

is a flow chart illustrating the inputs for the golf ball properties.





FIG. 1C

is a flow chart illustrating the inputs for the pre-impact swing properties.





FIG. 1D

is a flow chart of the inputs for the ball launch parameters.





FIG. 1E

is a flow chart of the outputs that are generated for the predicted performance.





FIG. 2

is a perspective view of the monitoring system of the present invention.





FIG. 3

is a front view of a golf club with markers for use in determining the pre-impact properties.





FIG. 3A

is a graphic of global coordinates of the markers on the golf club of FIG.


3


.





FIG. 4

is an image frame of a golfer's swing composed of a multitude of pre-impact exposures.





FIG. 5

illustrates an input screen.





FIG. 6

is an illustration of markers of a golf club on a three-dimensional plot for six pre-impact exposures.





FIG. 6A

is a three-dimensional plot of the extrapolated head position and orientation.





FIG. 6B

is a graphic of global coordinates of the markers of FIG.


6


.





FIG. 7

is a graphic of an input menu for impact locations.





FIG. 8

is a flow chart of the components of the pre-swing properties of FIG.


1


.





FIG. 9

is a table of the image times (in microseconds) of

FIG. 8

for Golfer A and Golfer B.





FIG. 10

is a table of the measured points (in millimeters) of

FIG. 8

for Golfer A and Golfer B.





FIG. 11

is a table of the static image points (in millimeters) of

FIG. 8

for Golfer A and Golfer B.





FIG. 12

is a table of the golf club head properties of

FIGS. 1 and 1A

for Golfer A and Golfer B.





FIG. 13

is a table of the pre-impact swing properties of

FIGS. 1 and 1C

for Golfer A and Golfer B.





FIG. 14

is a table of the golf ball properties of

FIGS. 1 and 1B

for Golfer A and Golfer B.





FIG. 15

is a table of the ball launch parameters of

FIGS. 1 and 1D

for Golfer A and Golfer B.





FIG. 16

is a table of the atmospheric conditions of

FIG. 1

for a warm day and a cold day.





FIG. 17

is a table of the predicted performance of

FIGS. 1 and 1E

for Golfer A and Golfer B.











DETAILED DESCRIPTION OF THE INVENTION




As shown in

FIG. 1

, a method for predicting a golfer's ball striking performance is generally designated


200


. The method


200


commences with inputting information on a specific golf club, specific golf ball, and the swing characteristics of a golfer. At block


202


, the club head properties of the specific golf club are selected from a database of stored and previously collected club head information. The specific information for the club head properties is set forth in greater detail below. At block


204


, the pre-impact swing properties of the golfer are collected and stored in a database. The specific information for the golfer's pre-impact swing properties is set forth in greater detail below. At block


206


, the golf ball properties of the specific golf ball are selected from a database of stored and previously collected golf ball information. The specific information for the golf ball properties is set forth in greater detail below.




At block


208


, the information from blocks


202


,


204


and


206


are inputted into a rigid body code. The rigid body code is explained in greater detail below. At block


210


, the rigid body code is used to generate a plurality of ball launch parameters. At block


212


, information concerning the atmospheric conditions is selected from a database of stored atmospheric conditions. At block


214


, information concerning the lift and drag properties of the golf ball are collected and stored. The lift and drag properties of golf balls are measured using conventional methods such as disclosed in U.S. Pat. No. 6,186,002, entitled Method For Determining Coefficients Of Lift And Drag Of A Golf Ball, which is hereby incorporated by reference in its entirety. The lift and drag coefficients of a number of golf balls at specific Reynolds numbers are disclosed in U.S. Pat. No. 6,224,499, entitled A Golf Ball With Multiple Sets Of Dimples, which pertinent parts are hereby incorporated by reference.




At block


216


, the ball launch parameters, the atmospheric conditions and the lift and drag properties are inputted into a trajectory code. At block


218


, the trajectory code is utilized to predict the performance of the golfer when swinging the specific golf club, with the specific golf ball under the specific atmospheric conditions. Trajectory codes are known in the industry, and one such code is disclosed in the afore-mentioned U.S. Pat. No. 6,186,002. The USGA has such a trajectory code available for purchase.





FIG. 1A

is a flow chart illustrating the inputs for the golf club head properties of block


202


. The measurements for the face properties are collected at block


401


. The face properties include the face geometry, the face center, the bulge radius and the roll radius. The measurements for the mass properties of the golf club head are collected or recalled from a database at block


402


. The mass properties include the inertia tensor, the mass of the club head, and the center of gravity location. The measurement for the coefficient of restitution of the golf club head using a specific golf ball is collected at block


403


. The measurements for the loft and lie angles of the golf club head are collected at block


404


. The data collected at blocks


401


-


404


is inputted to create the golf club head properties at block


202


of FIG.


1


.





FIG. 1B

is a flow chart illustrating the inputs for the golf ball properties of block


206


. The measurement of the mass of the golf ball is collected at block


405


. The measurement of the radius of the golf ball is collected at block


406


. The measurement of the moment of inertia of the golf ball is collected at block


407


. The measurement of the coefficient of restitution of the golf ball is collected at block


408


. The data collected at blocks


405


-


408


is inputted to create the golf ball properties at block


206


of FIG.


1


.





FIG. 1C

is a flow chart illustrating the inputs for the pre-impact swing properties of block


204


. The measurement of the linear velocity of the golf club being swung by the golfer is collected at block


409


. The measurement of the angular velocity of the golf club being swung by the golfer is collected at block


410


. The measurement of the golf club head orientation is collected at block


411


. The information of the club head impact location with the golf ball is determined at block


412


. The data collected at blocks


409


-


412


is inputted to create the pre-impact swing properties at block


204


of FIG.


1


.





FIG. 1D

is a flow chart of the inputs for the ball launch parameters at block


214


of FIG.


1


. The post impact linear velocity of the golf ball is calculated at block


416


. The post impact angular velocity of the golf ball is calculated at block


417


. The launch angle of the golf ball is calculated at block


418


. The side angle of the golf ball is calculated at block


419


. The speed of the golf ball is calculated at block


420


. The spin of the golf ball is calculated at block


421


. The spin axis of the golf ball is calculated at block


421


. The information from blocks


416


-


421


is inputted to the ball launch parameters at block


214


of FIG.


1


.





FIG. 1E

is a flow chart of the outputs from the trajectory code that are generated for the predicted performance of block


218


of FIG.


1


. Block


422


is the predicted total distance of the golf ball if struck with a specific golf club by a golfer. Block


423


is the predicted total dispersion of the golf ball if struck with a specific golf club by a golfer. Block


424


is the predicted trajectory shape (available in 3D or 2D) of the golf ball if struck with a specific golf club by a golfer. Block


425


is the predicted trajectory apex of the golf ball if struck with a specific golf club by a golfer.




The golf club head properties of block


202


that are collected and stored in the system include the mass of the golf club head, the face geometry, the face center location, the bulge radius of the face, the roll radius of the face, the loft angle of the golf club head, the lie angle of the golf club head, the coefficient of restitution (“COR”) of the golf club head, the location of the center of gravity, CG, of the golf club head relative to the impact location of the face, and the inertia tensor of the golf club head about the CG.




The mass, bulge and roll radii, loft and lie angles, face geometry and face center are determined using conventional methods well known in the golf industry. The inertia tensor is calculated using: the moment of inertia about the x-axis, Ixx; the moment of inertia about the y-axis, Iyy; the moment of inertia about the z-axis, Izz; the product of inertia Ixy; the product of inertia Izy; and the product of inertia Izx. The CG and the MOI of the club head are determined according to the teachings of co-pending U.S. patent application Ser. No. 09/916,374, entitled High Moment of Inertia Composite Golf Club, filed Feb. 27, 2001, assigned to Callaway Golf Company, the assignee of the present application, and hereby incorporated by reference in its entirety. The products of inertia Ixy, Ixz and Izy are determined according to the teachings of co-pending U.S. patent application Ser. No. 09/916,374, entitled Large Volume Driver Head with High Moments of Inertia, filed Jul. 26, 2001, assigned to Callaway Golf Company, the assignee of the present application, and hereby incorporated by reference in its entirety.




The COR of the golf club head is determined using a method used by the United States Golf Association (“USGA”) and disclosed at www.usga.org, or using the method and system disclosed in U.S. Pat. No. 6,585,605, entitled Measurement Of The Coefficient Of Restitution Of A Golf Club, assigned to Callaway Golf Company, the assignee of the present application, and hereby incorporated by reference in its entirety. However, the COR of the golf club head is predicated on the golf ball, and will vary for different types of golf balls.




The golf ball properties of block


206


that are stored and collected include the mass of the golf ball (the Rules of Golf, as set forth by the USGA and the R&A, limit the mass to 45 grams or less), the radius of the golf ball (the Rules of Golf require a diameter of at least 1.68 inches), the COR of the golf ball and the MOI of the golf ball. The MOI of the golf ball may be determined using method well known in the industry. One such method is disclosed in U.S. Pat. No. 5,899,822, which pertinent parts are hereby incorporated by reference. The COR is determined using a method such as disclosed in U.S. Pat. No. 6,443,858, entitled Golf Ball With A High Coefficient Of Restitution, assigned to Callaway Golf Company, the assignee of the present application, and which pertinent parts are hereby incorporated by reference.




The pre-impact swing properties are preferably determined using an acquisition system such as disclosed in U.S. Pat. No. 6,431,990, entitled System And Method For Measuring A Golfer's Ball Striking Parameters, assigned to Callaway Golf Company, the assignee of the present application, and hereby incorporated by reference in its entirety. However, those skilled in the pertinent art will recognize that other acquisition systems may be used to determine the pre-impact swing properties.




The pre-impact swing properties include golf club head orientation, golf club head velocity, and golf club spin. The golf club head orientation includes dynamic lie, loft and face angle of the golf club head. The golf club head velocity includes path of the golf club head and attack of the golf club head.




The acquisition system


20


generally includes a computer


22


, a camera structure


24


with a first camera unit


26


, a second camera unit


28


and a trigger device


30


, a teed golf ball


32


and a golf club


33


. The acquisition system


20


is designed to operate on-course, at a driving range, inside a retail store/showroom, or at similar facilities.




The first camera unit


26


includes a first camera


40


and flash units


42




a


and


42




b


. The second camera unit


28


includes a second camera


44


and flash units


46




a


and


46




b


. A preferred camera is a charged coupled device (“CCD”) camera available from Wintriss Engineering of California under the product name OPSIS1300 camera.




The trigger device


30


includes a receiver


48


and a transmitter


60


. The transmitter


60


is preferably mounted on the frame


34


a predetermined distance from the camera units


26


and


28


. A preferred trigger device is a laser device that transmits a laser beam from the transmitter


60


to the receiver


48


and is triggered when broken by a club swung toward the teed golf ball


32


. The teed golf ball


32


includes a golf ball


66


and a tee


68


. Other trigger devices such as optical detectors and audible detectors may be used with the present invention. The teed golf ball


32


is a predetermined length from the frame


34


, L


1


, and this length is preferably 38.5 inches. However, those skilled in the pertinent art will recognize that the length may vary depending on the location and the placement of the first and second camera units


26


and


28


. The transmitter


50


is preferably disposed from 10 inches to 14 inches from the cameras


40


and


44


. The receiver


48


and transmitter


60


, and hence the laser beam, are positioned in front of the teed ball


32


such that a club swing will break the beam, and hence trigger the trigger device


30


prior to impact with the teed ball


32


. As explained in greater detail below, the triggering of the trigger device


30


will generate a command to the first and second camera units


26


and


28


to begin taking exposures of the golf club


33


prior to impact with the teed golf ball


32


. The data collected is sent to the computer


22


via a cable


62


, which is connected to the receiver


48


and the first and second camera units


26


and


28


. The computer


22


has a monitor


64


for displaying an image frame generated by the exposures taken by the first and second camera units


26


and


28


. The image frame is the field of view of the cameras


40


and


44


.




A first golf club


33


is preferably prepared for use with the system


20


to determine the pre-impact properties. Typically, the acquisition system


20


will take the average of ten swings from a single golfer to determine the pre-impact properties. These pre-impact swing properties will then be used to predict that particular golfer's performance with other golf clubs and golf balls under various atmospheric conditions without the golfer having to actually strike different golf balls with different golf clubs under various conditions.




As shown in

FIG. 3

, the golf club


33


has a club head


50


, a shaft


52


, a face


54


, scorelines


56


, a toe end


58


and a heel end


59


. A plurality of markers are preferably placed on the golf club


33


to highlight specific locations of the golf club


33


. Only three marks are needed on the golf club to determine the pre-impact swing properties. A preferred embodiment is shown in FIG.


3


. However, the acquisition system


20


is capable of using the basic features of the golf club


33


such as the scorelines, without the need for markers. A first marker


301


is placed on a tip end of the shaft


52


. A second marker


302


is placed lower on the tip end of the shaft


52


than the first marker


301


. A third marker


303


is placed on the high toe end


58


of the club head


50


. A fourth marker


304


is placed on a low toe end of the face


54


. A fifth marker


305


is placed on a high toe end of the face


54


. A sixth marker


306


is placed on a high heel end of the face


54


. A seventh marker


307


is placed on a low heel end of the face


54


. An eighth marker


308


is placed in the center of the face


54


.




An image frame of the golf club


33


of

FIG. 3

is created by the acquisition system


20


to determine the location of the markers


304


-


308


or the scorelines relative to the markers


301


-


303


. The loft, lie and face angle of the golf club are determined relative to the markers


301


-


303


. This allows for the true golf club head


50


orientation to be measured from the markers


301


-


303


. It is preferred that the markers


301


-


308


are highly reflective adhesive labels or be inherent with the golf club design. The markers


301


-


308


are preferred to be highly reflective since the cameras


40


and


44


are programmed to search for two or three points that have a certain brightness such as 200 out of a grey scale of 0-255. Two or more pre-impact exposures of the golf club


33


being swung by the golfer are acquired by the system


20


. A preferred range of pre-impact exposures is three to nine, with six pre-impact exposures being the most preferred number.

FIG. 5

illustrates an input screen to input the number and spacing of the exposures, the threshold level, the size of the points and the rigid relationship from the initial orientation screen.





FIG. 4

is an image frame of four pre-impact exposures for a golfer swinging a golf club


33


. A first exposure


102




a


, a second exposure


102




b


, a third exposure


102




c


and a fourth exposure


102




d


illustrate the golf club


33


prior to impact with the golf ball


66


. The markers


301


-


303


are located in two dimensions, and then correlated in three dimensions. The marker


303


is correlated to the markers


301


and


302


on the shaft


52


. The position of the face


54


and the tee ball


32


prior to impact our reconstructed and inputted to determine the pre-impact properties.





FIG. 6

is an illustration of the markers


301


,


302


,


303


and


308


of a golf club


33


on a three-dimensional plot for six pre-impact exposures


102




a


-


102




f


. The markers


301


,


302


,


303


and


308


for each exposure


102




a


-


102




f


are designated


301




a


,


301




b


,


301




c


, . . . etc. The global coordinates of the markers of

FIG. 6

are illustrated in FIG.


6


B.




In the example of

FIG. 6

, the first exposure


102




a


is taken at 100 microseconds after the trigger. The second exposure


102




b


is taken at 474.6 microseconds after the trigger. The third exposure


102




c


is taken at 849.3 microseconds after the trigger. The fourth exposure


102




d


is taken at 1223.9 microseconds after the trigger. The fifth exposure


102




e


is taken at 1598.6 microseconds after the trigger. The sixth exposure


102




f


is taken at 1973.2 microseconds after the trigger. In addition the location of the golf ball prior to impact is found. The ball location may be found prior to the player starting the back swing, assumed to be the same location from a previous shot, or found in the image. To determine the orientation of the golf club face


54


prior to impact the orientation of the markers discussed previously in

FIG. 3

are oriented relative to the markers in FIG.


6


. Where Ra and Ta are the rotation and translation matrix between


301




a


,


302




a


,


303




a


and


301


,


302


,


303


and Rb and Tb are the rotation and translation matrix between


301




b


,


302




b


,


303




b


etc.




[Point


308




a


]=[Point


308


]*Ra+Ta.




[Point


308




b


]=[Point


308


]*Rb+Tb, etc.




Using the equation, any point previously found on the golf club face


54


can be modeled from the measured points. From point


308




f


and the tee ball location, an estimate of the extrapolation time to impact can be made. Then, each series of points is curve fit with a second order curve fit and evaluated at the extrapolated time to give points


301




g


,


302




g


, and


303




g


of FIG.


6


A. The extrapolated position data is used to calculate a new rotation and translation matrix and


308




g


is located. Any feature on the face


54


can be rotated and translated to the impact position using this method and a vector normal to the face


54


created and located on the center of the face


54


. The initial impact location is defined as the location from the center of the tee ball


66


along the direction normal to the golf club face


54


and intersecting with the club head


50


. The initial impact location needs to be modified to correct for the amount that the ball will deform on the golf club face. A simple method is to correct the vertical impact location Vertical Correction=12.5/25.4*sin(loft−attack angle). Lateral Correction=12.5/25.4*sin(face angle−path angle). More complex methods can be used to correct for the initial impact location. The 12.5 mm is dependent on the swing speed of the club and is based on a 100 MPH swing. The slower the golf club head speed, the smaller the value.


308




a


-


308




g


and the image times are curve fit and Vx, Vy, and Vz are resolved for Rigid Body Code.




Based on these six exposures


102




a


-


102




f


, the predicted impact is at 2962.4 microseconds after the trigger. Based on this information, the pre-impact swing properties are calculated for the golfer.




Once the pre-impact swing properties are determined (calculated), the rigid body code is used to predict the ball launch parameters. The rigid body code solves the impact problem using conservation of linear and angular momentum, which gives the complete motion of the two rigid bodies. The impulses are calculated using the definition of impulse, and the equations are set forth below. The coordinate system used for the impulse equations is set forth below. The impulse-momentum method does not take in account the time history of the impact event. The collision is described at only the instant before contact and the instant after contact. The force transmitted from the club head to the ball is equal and opposite to the force transmitted from the ball to the club head. These forces are conveniently summed up over the period of time in which the two objects are in contact, and they are called the linear and angular impulses.




The present invention assumes that both the golf ball


66


and the golf club head


50


are unconstrained rigid bodies, even though the golf club head


50


is obviously connected to the shaft


52


, and the ball


66


is not floating in air upon impact with the golf club head


50


. For the golf club head


50


, the assumption of an unconstrained rigid body is that the impact with the golf ball


66


occurs within a very short time frame (microseconds), that only a small portion of the tip of the shaft


52


contributes to the impact. For the golf ball


66


, the impulse due to friction between itself and the surface it is placed upon (e.g. tee, mat or ground) is very small in magnitude relative to the impulse due to the impact with the golf club head


50


, and thus this friction is ignored in the calculations.




In addition to the normal coefficient of restitution, which governs the normal component of velocity during the impact, there are coefficients of restitution that govern the tangential components of velocity. The additional coefficients of restitution are determined experimentally.




The absolute performance numbers are defined in the global coordinate system, or the global frame. This coordinate system has the origin at the center of the golf ball, one axis points toward the intended final destination of the shot, one axis points straight up into the air, and the third axis is normal to both of the first two axis. The global coordinate system preferably follows the right hand rule.




The coordinate system used for the analysis is referred to as the impact coordinate system, or the impact frame. This frame is defined relative to the global frame for complete analysis of a golf shot. The impact frame is determined by the surface normal at the impact location on the golf club head


50


. The positive z-direction is defined as the normal outward from the golf club head


50


. The plane tangent to the point of impact contains both the x-axis and the y-axis. For ease of calculation, the x-axis is arbitrarily chosen to be parallel to the global ground plane, and thus the yz-plane is normal to the ground plane. The impact frame incorporates the loft, bulge and roll of a club head, and also includes the net result of the golf swing. Dynamic loft, open or close to the face, and toe down all measured for definition of the impact frame. Motion in the impact frame is converted to equivalent motion in the global frame since the relationship between the global coordinate system and the impact coordinate system is known. The post impact motion of the golf ball


66


is used as inputs in the Trajectory Code, and the distance and deviation of the shot is calculated by the present invention.




The symbols are defined as below:




{right arrow over (i)}=(


1




0




0


), the unit vector in the x-direction.




{right arrow over (j)}=(


0




1




0


), the unit vector in the y-direction.




{right arrow over (k)}=(


0




0




1


), the unit vector in the z-direction.




m


1


, the mass of the club head.




m


2


, the mass of the golf ball.












[
I
]

1

=

[




I

xx
,
1





-

I

xy
,
1






-

I

xz
,
1








-

I

xy
,
1






I

yy
,
1





-

I

yz
,
1








-

I

xz
,
1






-

I

yz
,
1






I

zz
,
1





]


,





the





inertia





tensor





of





the





club






head
.
















[
I
]

2

=

[




I

xx
,
2





-

I

xy
,
2






-

I

xz
,
2








-

I

xy
,
2






I

yy
,
2





-

I

yz
,
2








-

I

xz
,
2






-

I

yz
,
2






I

zz
,
2





]


,





the





inertia





tensor





of





the





golf






ball
.




















{right arrow over (r)}


1


=(a


1


b


1


c


1


), the vector from point of impact to the center of gravity of the club head.




{right arrow over (r)}


2


=(a


2


b


2


c


2


), the vector from point of impact to the center of gravity of the golf ball.




{right arrow over (r)}


3


=−{right arrow over (r)}


1


+{right arrow over (r)}


2


=(−a


1


+a


2


−b


1


+b


2


−c


1


+c


2


)=(a


3


b


3


c


3


), the vector from center of gravity of club head to the center of gravity of the golf ball.




{right arrow over (ν)}


1,i


=(ν


x,1,i


ν


y,1,i


ν


z,1,i


), the velocity of the club head before impact.




{right arrow over (ν)}


1,f


=(ν


x,1,f


ν


y,1,f


ν


z,1,f


), the velocity of the club head after impact.




{right arrow over (ν)}


1,i


=(ν


x,1,i


ν


y,1,i


ν


z,1,i


), the velocity of the golf ball before impact.




{right arrow over (ν)}


2,f


=(ν


x,2,f


ν


y,2,f


ν


z,2,f


), the velocity of the golf ball after impact.




{right arrow over (ω)}


1,i


=(ω


x,1,i


ω


y,1,i


ω


z,1,i


), the angular velocity of the club head before impact.




{right arrow over (ω)}


1,f


=(ω


x,1,f


ω


y,1,f


ω


z,1,f


), the angular velocity of the club head after impact.




{right arrow over (ω)}


1,i


=(ω


x,2,i


ω


y,2,i


ω


z,2,i


), the angular velocity of the golf ball before impact.




{right arrow over (ω)}


2,f


=(ω


x,2,f


ω


y,2,f


ω


z,2,f


), the angular velocity of the golf ball after impact.








[
e
]

=

[




e
xx




e
xy




e
xz






e
xy




e
yy




e
yz






e
xz




e
yz




e
zz




]


,

the  coefficient  of  restitution  matrix.











[L]=m{right arrow over (ν)}, definition of linear momentum.




[H]=[I]{right arrow over (ω)}, definition of angular momentum.




Conservation of linear momentum:








m




1


{right arrow over (ν)}


1,f




+m




2


{right arrow over (ν)}


2,f




=m




1


{right arrow over (ν)}


1,i




+m




2


{right arrow over (ν)}


2,i


  


B


1


-B


3






Conservation of angular momentum:













[
I
]

1




ω



1
,
f



+



[
I
]

2




ω



2
,
f



+


m
1



[






-

c
1




v

y
,
1
,
f



+


b
1



v

z
,
1
,
f











c
1



v

x
,
1
,
f



-


a
1



v

z
,
1
,
f











a
1



v

y
,
1
,
f



-


b
1



v

x
,
1
,
f







]


+


m
2



[






-

c
2




v

y
,
2
,
f



+


b
2



v

z
,
2
,
f











c
2



v

x
,
2
,
f



-


a
2



v

z
,
2
,
f











a
2



v

y
,
2
,
f



-


b
2



v

x
,
2
,
f







]



=




[
I
]

1




ω



1
,
i



+



[
I
]

2




ω



2
,
i



+


m
1



[






-

c
1




v

y
,
1
,
i



+


b
1



v

z
,
1
,
i











c
1



v

x
,
1
,
i



-


a
1



v

z
,
1
,
i











a
1



v

y
,
1
,
i



-


b
1



v

x
,
1
,
i







]


+


m
2



[






-

c
2




v

y
,
2
,
i



+


b
2



v

z
,
2
,
i











c
2



v

x
,
2
,
i



-


a
2



v

z
,
2
,
i











a
2



v

y
,
2
,
i



-


b
2



v

x
,
2
,
i







]







B4


-


B6













The definition of coefficients of restitution:










-


[
e
]

[












(


v

x
,
2
,
i


+


i


·

(



ω



2
,
i


×

(

-


r


2


)


)



)

-

(


v

x
,
1
,
i


+


i


·

(



ω



1
,
i


×

(

-


r


1


)


)



)








(


v

y
,
2
,
i


+


j


·

(



ω



2
,
i


×

(

-


r


2


)


)



)

-

(


v

y
,
1
,
i


+


j


·

(



ω



1
,
i


×

(

-


r


1


)


)



)











(


v

z
,
2
,
i


+


k


·

(



ω



2
,
i


×

(

-


r


2


)


)



)

-

(


v

z
,
1
,
i


+


k


·

(



ω



1
,
i


×

(

-


r


1


)


)



)





]


=

[












(


v

x
,
2
,
f


+


i


·

(



ω



2
,
f


×

(

-


r


2


)


)



)

-

(


v

x
,
1
,
f


+


i


·

(



ω



1
,
f


×

(

-


r


1


)


)



)








(


v

y
,
2
,
f


+


j


·

(



ω



2
,
f


×

(

-


r


2


)


)



)

-

(


v

y
,
1
,
f


+


j


·

(



ω



1
,
f


×

(

-


r


1


)


)



)











(


v

z
,
2
,
f


+


k


·

(



ω



2
,
f


×

(

-


r


2


)


)



)

-

(


v

z
,
1
,
f


+


k


·

(



ω



1
,
f


×

(

-


r


1


)


)



)









]





B7-B9













The tangential impulse on the ball causes both rotation and translation:














m
2



[









c
2



(


v

y
,
2
,
f


-

v

y
,
2
,
i



)


-


b
2



(


v

z
,
2
,
f


-

v

z
,
2
,
i



)









-


c
2



(


v

x
,
2
,
f


-

v

x
,
2
,
i



)



+


a
2



(


v

z
,
2
,
f


-

v

z
,
2
,
i



)













b
2



(


v

x
,
2
,
f


-

v

x
,
2
,
i



)


-


a
2



(


v

y
,
2
,
f


-

v

y
,
2
,
i



)






]


=



[
I
]

2



[








ω

x
,
2
,
f


-

ω

x
,
2
,
i









ω

y
,
2
,
f


-

ω

y
,
2
,
i












ω

z
,
2
,
f


-

ω

z
,
2
,
i






]
















B10-B12













Equations B1-B12 can be combined to form a system of linear equations of the form:






[A]{x}={B}  B13






where [A], and {B} are determined from the known velocities before the impact, the mass properties of the golf ball


66


and golf club head


50


, the impact location relative to the center of gravity of the golf ball


66


and the golf club head


50


, and the surface normal at the point of impact. {x} contains all the post impact velocities (linear and angular), and is solved by pre-multiplying {B} by the inverse of [A], or any other method in solving system of equations in linear algebra.




When the golf ball


66


is sitting on the tee


68


, it is in equilibrium. The golf ball


66


will not move until a force that's greater than F


m


, the maximum static friction force between the golf ball


66


and the tee


68


, is applied on the golf ball


66


.








F




m





s




N=μ




s




m




2




g


  C1






μ


s


is the static coefficient of friction and g is gravity.




For a golf ball


66


with 45 grams of mass, and a μ


s


of 0.3,








F




m





s




mg


=(0.3)(0.045)(9.81)=0.132


N








Assume this force is applied on the golf ball


66


for the duration of an impact of 0.0005 sec (which is an overestimation of the actual impulse), then the impulse, L, on the golf ball


66


is:








L


=(0.132)(0.0005)=0.0000662


N·s








This impulse, L, would cause the golf ball


66


to move at 0.00147 m/s (or 0.00483 ft/sec), and rotate at 8.08 rad/sec (or 77.1 rpm). Both of these numbers are small relative to the range of numbers normally seen for irons and woods. If the rigid body code of the present invention were to be applied to putters, then it would be preferable to include the friction force between the green and the golf ball


66


for the analysis.







[
e
]

=

[




e
xx




e
xy




e
xz






e
xy




e
yy




e
yz






e
xz




e
yz




e
zz




]











Each of the individual terms in the above matrix, e


ij


, where i=x, y, z, and j=x, y, z, relates the velocity in the i-direction to the j-direction. Each of the diagonal terms, where i=j, indicate the relationship in velocity of one of the axis, x, y, or z, before and after the impact. Let x, y, z be the axis defined in the impact frame. The term e


zz


includes all the energy that is lost in the impact in the normal direction of impact. e


xx


and e


yy


are account for the complicated interaction between the golf ball


66


and the golf club head


50


in the tangential plane by addressing the end result. In general, the off diagonal terms e


ij


, where i≠j, are equal to zero for isotropic materials.




As shown in

FIG. 7

, in predicting the performance of a golf ball struck by a golfer with a specific golf club under predetermined atmospheric conditions, an operator has the option of inputting an impact of the face


54


at a certain location regardless of the true location of impact. This allows for prediction of the performance of the golf club


33


for toe shots, heel shots and center shots. The type of golf ball may be selected, the type of golf club may be selected, the atmospheric conditions including wind speed, direction, relative humidity, air pressure, temperature and the terrain may be selected by the operator to predict a golfer's performance using these input parameters along with the pre-impact swing properties for the golfer.




The method of the present invention for predicting the performance of two different golfers, using two different golf clubs, with two different golf balls under two different atmospheric conditions is illustrated in

FIGS. 8-17

. Golfer B has a higher swing speed than Golfer A. Golfers A and B swing a test club 10 times for an average of the swing of each golfer. The predicted performances are for a golf club head


50


composed of steel and a golf club head composed of titanium, a 2-piece golf ball with an ionomer blend cover and a three-piece (wound) golf ball with a balata cover, and atmospheric conditions of a warm day and a cold day.





FIG. 8

is a flow chart of the components of the pre-swing properties of block


204


of FIG.


1


. The components or inputs include the image times at block


203


.


7


, the measured points at block


203


.


8


and the static imaged points at block


203


.


9


.

FIG. 9

is a table of the image times (in microseconds) of block


203


.


7


for Golfer A and Golfer B.

FIG. 10

is a table of the measured points (in millimeters) of block


203


.


8


for Golfer A and Golfer B.

FIG. 11

is a table of the static image points (in millimeters) of block


203


.


9


for Golfer A and Golfer B.





FIG. 12

is a table of the golf club head properties of block


202


for golf club heads


50


composed of titanium (Ti) and steel. Blocks


401


-


404


of

FIG. 1A

are included along with optional hosel height and Spin COR inputs.





FIG. 13

is a table of the pre-impact swing properties of block


204


for each of the Golfers A and B. The table includes information for blocks


409


-


412


of FIG.


1


C.





FIG. 14

is a table of the golf ball properties of block


206


with information for blocks


405


-


408


of FIG.


1


B.





FIG. 15

is a table of the ball launch parameters of block


210


generated by the rigid body code. The table includes information for blocks


416


-


422


of FIG.


1


D.





FIG. 16

is a table of the atmospheric conditions of block


214


.





FIG. 17

is a table of the predicted performance of block


218


which is generated by the trajectory code. The table includes information for blocks


422


-


425


of FIG.


1


E.




From the foregoing it is believed that those skilled in the pertinent art will recognize the meritorious advancement of this invention and will readily understand that while the present invention has been described in association with a preferred embodiment thereof, and other embodiments illustrated in the accompanying drawings, numerous changes, modifications and substitutions of equivalents may be made therein without departing from the spirit and scope of this invention which is intended to be unlimited by the foregoing except as may appear in the following appended claims. Therefore, the embodiments of the invention in which an exclusive property or privilege is claimed are defined in the following appended claims.



Claims
  • 1. A method for predicting a golfer's ball striking performance, the method comprising:determining a plurality of pre-impact swing properties for the golfer based on the golfer's swing with a first golf club, the plurality of pre-impact swing properties including an impact location and an angular velocity, a linear velocity and an orientation of a golf club head; generating a plurality of ball launch parameters from a plurality of club head properties of the first golf club, a plurality of ball properties of a first golf ball, and the plurality of pre-impact swing properties, the plurality of club head properties including a plurality of face properties and a plurality of mass properties, the plurality of ball properties including a mass, a radius, a moment of inertia and a coefficient of restitution of the golf ball; imputing into a trajectory code the plurality of ball launch parameters, a plurality of first atmospheric conditions, and a plurality of lift and drag properties for the first golf ball; and generating a predicted performance from the trajectory code of the first golf ball if struck with the first golf club by the golfer under the first atmospheric conditions.
  • 2. The method according to claim 1, wherein the plurality of face properties includes a face geometry, a face center, a bulge radius and a roll radius, and wherein the plurality of mass properties includes an inertial tensor, a mass of the club head and a center of gravity location.
  • 3. The method according to claim 1, wherein the plurality of ball launch parameters includes a ball speed, linear and angular velocities, launch and side angles of the golf ball, a ball spin and a spin axis of the golf ball.
  • 4. The method according to claim 1, wherein generating the predicted performance includes predicting a trajectory shape, a trajectory apex, flight and roll distances of the golf ball, and a dispersion of the golf ball.
  • 5. The method according to claim 1, further comprising:inputting into the trajectory code the plurality of ball launch parameters, a plurality of second atmospheric conditions, and the plurality of lift and drag properties for the first ball; and generating a predicted performance from the trajectory code of the first golf ball if struck by the golfer with the first golf club under the second atmospheric conditions.
  • 6. The method according to claim 1, further comprising:generating a second plurality of ball launch parameters from a plurality of club head properties of a second golf club, the plurality of ball properties of the first golf ball, and the plurality of pre-impact swing properties; inputting into the trajectory code the second plurality of ball launch parameters, the plurality of lift and drag properties for the first golf ball, and a subset of atmospheric conditions selected from a set of atmospheric conditions that includes at least a first subset comprised of the plurality of first atmospheric conditions and a second subset comprised of a plurality of second atmospheric conditions; and generating a predicted performance from the trajectory code of the first golf ball if struck by the golfer with the second golf club under the selected subset of atmospheric conditions.
  • 7. The method according to claim 1, further comprising:generating a second plurality of ball launch parameters from the plurality of club head properties of the first golf club, a plurality of ball properties of a second golf ball, and the plurality of pre-impact swing properties; inputting into the trajectory code the second plurality of ball launch parameters, a plurality of lift and drag properties for the second golf ball, and a subset of atmospheric conditions selected from a set of atmospheric conditions that includes at least a first subset comprised of the plurality of first atmospheric conditions and a second subset comprised of a plurality of second atmospheric conditions; and generating a predicted performance from the trajectory code of the second golf ball if struck by the golfer with the first golf club under the selected subset of atmospheric conditions.
  • 8. The method according to claim 1, further comprising:generating a second plurality of ball launch parameters from a plurality of club head properties of a second golf club, a plurality of ball properties of a second golf ball, and the plurality of pre-impact swing properties; inputting into the trajectory code the second plurality of ball launch parameters, a plurality of lift and drag properties for the second golf ball, and a subset of atmospheric conditions selected from a set of atmospheric conditions that includes at least a first subset comprised of the plurality of first atmospheric conditions and a second subset comprised of a plurality of second atmospheric conditions; and generating a predicted performance from the trajectory code of the second golf ball if struck by the golfer with the second golf club under the selected subset of atmospheric conditions.
CROSS REFERENCES TO RELATED APPLICATIONS

This application is a continuation application of co-pending U.S. patent application Ser. No. 10/248,332, filed on Jan. 9, 2003, now U.S. Pat. No. 6,602,144 which is a continuation of U.S. patent application Ser. No. 09/683,396 filed on Dec. 21, 2001, now U.S. Pat. No. 6,506,124.

US Referenced Citations (5)
Number Name Date Kind
4136387 Sullivan et al. Jan 1979 A
4375887 Lynch et al. Mar 1983 A
6186002 Lieberman et al. Feb 2001 B1
6506124 Manwaring et al. Jan 2003 B1
6602144 Manwaring et al. Aug 2003 B2
Continuations (2)
Number Date Country
Parent 10/248332 Jan 2003 US
Child 10/633200 US
Parent 09/683396 Dec 2001 US
Child 10/248332 US