DESCRIPTION OF THE PREFERRED EMBODIMENT(S)

[0029] Referring to the accompanying Figures wherein like reference numbers refer to like components, there is shown an electronic golf swing analyzing system, generally indicated by reference number 10 , that uses an analyzer 12 attached by a serial communications cable to a desktop or laptop computer 70 with a golf swing analyzing software application 40 loaded into the memory 72 of the computer 70 . The software application 40 is designed to give the user immediate feedback information regarding the golf swing performed on the analyzer 12 .

[0030] More specifically, the analyzer 12 includes an IR sensor base 14 and a support platform 24 , pivotally connected together along their adjacent longitudinally aligned edges 15 , 25 , respectively, by hinges 31 . The support platform 24 includes a U/S sensor base 34 that is rotated from a position inside a complementary-shaped storage cavity 30 formed on the support platform 24 to a rotated position, perpendicularly aligned to the top surface 26 . During use the IR sensor base 14 and support platform 24 , respectively, are unfolded onto a flat horizontally aligned position into a flat support surface. The U/S sensor base 34 is pivoted upward from its storage cavity 30 so that its bottom surface 35 faces a rectangular-shaped hitting area 20 located on the top surface 16 of the IR sensor base 14 .

[0031] In the preferred embodiment, the IR sensor base 14 and the support platform 24 each measure approximately 20 inches in length, 10 inches in width and 1½ inches in thickness. The U/S sensor base 34 measures approximately 10 inches in length, 5 inches in width and 1 inch in thickness. Mounted on the IR sensor base 34 are two symmetrical, triangular-shaped arrays of (IR) infrared sensors, generally referenced as 50 , 50 ′ centered about the target line 92 and positioned right and left, respectively, of the golf ball 90 . The outer IR sensor 50 A, 50 A′ on each array 50 , 50 ′, respectively, is positioned 3 inches left and right of the center of the golf ball 90 on the target line 92 . The two other sensor pairs in each array 50 , 50 ′, called inner IR sensors 50 B, 50 C, and 50 B′, 50 C′, respectively are positioned 1 inch right and left, respectively, of the center of the golf ball 90 and about ¾ inches above and ¾ inches below the target line 92 . The IR sensors 50 A, 50 B, 50 C, 50 A′, 50 B′ and 50 C′ are safely embedded below a rectangular shaped ¼ inch rubber pad 55 (5×10 inches in dimension), which is affixed with adhesive to the top surface of the IR sensor base 14 that covers the printed circuit board 53 on which the IR sensors 50 A, 50 B, 50 C, 50 A′, 50 B′, and 50 C′ are mounted. Each IR sensor 50 A, 50 B, 50 C, 50 A′, 50 B′, 50 C′, is aligned with a small (¾ inch diameter) hole 56 punched in the rubber pad 55 to allow transmission of infrared light. Because the two triangular arrays 50 , 50 ′ are symmetrically aligned on opposite sides of the center axis, the analyzer 12 may be used by both left- and right-handed golfers without requiring any mechanical change to the system 10 .

[0032] Mounted on the bottom surface 35 of the U/S sensor base 34 are two U/S sensors, generally referenced as 60 and 60 ′. The U/S sensors 60 , 60 ′ are commonly referred to as transducers. Each U/S sensor 60 , 60 ′ functions in “pulse-echo mode,” first as an ultrasonic transmitter, then, as an ultrasonic receiver. The U/S sensors 60 , 60 ′ are horizontally aligned with the bottom surface 35 of the sensor base 34 and parallel with the target line 92 . The U/S sensors 60 , 60 ′are axially aligned on opposite sides of the center axis 16 and aligned with the outer infrared sensors, 50 A, 50 A′, respectively. In the preferred embodiment, the U/S sensors 60 , 60 ′ are positioned on the sensor base 34 so that when the sensor base 34 is rotated vertically, the U/S sensors 60 , 60 ′ are positioned approximately one and one-half (1½) inches above the top surface of the IR sensor base 14 .

[0033] As shown in FIGS. 5 and 6 , each IR sensor 50 A, 50 B, 50 C and 50 A′, 50 B′ and 50 C includes an infrared emitter 54 and an adjacent infrared photodiode detector 78 . In the preferred embodiment, the infrared emitter 54 is a high power light emitting diode (LED). The infrared photodiode detector 78 is a gallium aluminum arsenide (GaAlAs) photodiode. The infrared emitter 54 and photodiode detector 78 are spectrally matched pairs of infrared components that are reliable, easily controlled with a micro-controller and relatively inexpensive. The LED produces a narrow (5 degree) cone of IR light, focused vertically relative to its centerline. The LED is pulsed by a 25 KHz signal (5 uS on, 35 uS off) resulting in a 12.5% duty cycle. Pulsing the IR LED at a relatively low duty cycle significantly increases the current that can safely be applied to the LED, which substantially increases the range that the adjacent photodiode can “see” the club head by detecting reflected IR beam from the bottom of the club head as it passes over the IR sensor arrays 50 , 50 .′

[0034] A sensor cap 57 is placed over each IR emitter 54 and adjacent photodiode detector 78 . In the preferred embodiment, the cap 57 is injection molded and made of light blocking material, such as black ABS plastic. Formed within the cap 57 are two optically separated round cavities 58 , 59 designed to receive the infrared emitter 54 and the photodiode detector 78 , respectively. The infrared emitter 54 and photodiode detector 78 on the six IR sensors 50 are all mounted on a printed circuit board 53 . During assembly, the printed circuit board 53 is positioned inside the IR support base 14 . The cap 57 rests on the printed circuit board 53 so each pair of infrared emitter 57 and photodiode detector 78 extends into the cap 57 . A cylindrical shaped bushing 67 is placed over each cap 67 . Located over the detector 78 and inside the photodiode detector's cavity 59 is a convex lens 69 . The lens 69 is injection molded from transparent polycarbonate and functions to gather any IR light that enters the cavity 59 through a narrow slot 63 on top of the cap 57 and to direct it toward the photodiode detector's active area. One additional component of each cap 57 , is a ¾″ round plastic IR bandpass filter, hereinafter called a IR filter 71 , that permits only a narrow bandwidth of IR light to be transmitted through the IR filter 71 and into the cavity 59 . During assembly, the IR filter 71 is placed on top of each cap 57 and held securely in place between a small lip on the nylon bushing's top inside circumference and the top of the cap 57 .

[0035] The high frequency U/S sensors 60 , 60 ′ operate at a frequency of 200 KHz. Such components are reliable, easily controlled with a micro-controller and relatively inexpensive. When a pulsed high voltage signal is applied to the U/S sensor 60 , 60 ′, the transmitter produces a sonic wave with most of its energy focused within a fifteen (15) degree cone, 7.5 degrees left or right of the centerline of the U/S sensor 60 , 60 ′.

[0036] A flat ribbon cable 77 extends between the IR sensor base 14 and U/S sensor base 34 to connect the printed circuit board 53 for the infrared sensors 50 A, 50 B, 50 C and 50 A′, 50 B′, 50 C′ to the micro-controller 76 . A wireless or wired link, such as a serial cable 83 connects the micro-controller 76 , located on the U/S sensor printed circuit board 75 to a personal computer. A 110-volt A.C. transformer 105 is provided for providing ±12 DC volt and 5 volt DC power to the analyzer 12 .

[0037] In the preferred embodiment, an optional artificial turf insert panel 110 is placed inside the cavity 30 during assembly to provide a continuous flat surface between the golf ball 90 and the U/S sensor base 34 . During disassembly, the insert panel 110 is removed from the cavity 30 so that the U/S sensor base 34 may be folded into the cavity 30 , as shown in FIG. 5 .

[0038] In the preferred embodiment, an optional stance base 47 is also provided that includes two hinged boxes 48 , 49 , each about sixteen inches (16″) by twenty inches (20″) in dimension and about one and one-half inches (1½″) high. The boxes 48 , 49 form a structure approximately twenty inches (20″) by thirty-two inches (32″) upon which the player stands to swing the golf club. Each box 48 , 49 includes a gridded mat, 86 , 87 , respectively, that provides visual reference lines parallel and perpendicular to the target line 92 . The stance base 47 is physically connected by a connector bridge 89 to the IR sensor base 14 . The bridge 89 is adjustable left and right, as well as in and out, relative to the analyzer 12 to accommodate players of different physical sizes, as well as left handed or right handed golfers.

[0039] The software application 40 provides three practice modes: (1) hitting a golf ball relative to a target line; (2) hitting a golf ball relative to a target located at a selected distance; and (3) collecting the average distance data for the short game by hitting different wedges with varying lengths of backswings. Along with selecting a specific practice mode, the user selects a club to use, which automatically links related club head loft and club head weight data to the computer 70 for making its trajectory calculations. The software application 40 also compensates for selected ball characteristics (compression and spin type), current environmental conditions (wind, barometric pressure, temperature and humidity) and the player's profile (left or right handed and ability level).

[0040] Theory of Operation

[0041] Club head velocity is a measure of how fast the club head 99 is moving at impact with the ball, which, along with the mass of the club head 99 , determines how much energy is available to be transferred to the golf ball 90 . Club face angle is a measure of whether the clubface is square, open or closed relative to the target line 92 at impact. Swing path angle is a measure of whether the club head 99 is traveling directly down the target line 92 or being pulled or pushed across the target line 92 at impact. By determining these three data, the distance that the golf ball 90 will travel, and the flight path of the ball relative to the target line 92 after impact may be accurately calculated.

[0042] When a player swings a golf club to hit a golf ball positioned on a rubber tee 94 on the rubber pad 5 of the IR support base 14 , the club head 99 passes over the outer IR sensor 50 or 50 ′. IR light emitted from the IR emitter on the outer IR sensor 50 A is reflected from the bottom of the club head to the adjacent photodiode detector. This reflected IR signal, when it is detected, starts a timer 76 in the micro-controller and triggers a burst of twenty (20) cycles of 200 KHz sonic energy from the U/S sensor 60 , 60 ′ aligned with the array 50 . The sonic waves quickly reach the club head 99 and are reflected back to the U/S sensor 60 , 60 ′. The micro-controller 76 is programmed to read the timer when the first echo above a set threshold voltage is detected. When the first ultrasonic echo is captured, the micro-controller 76 is programmed to start pulsing IR light from both of the inner IR sensors 50 B, 50 C in the array 50 . The micro-controller 76 remains in a tight loop, waiting for each of the two inner sensors 50 B, 50 C to automatically capture the micro-controller timer reading when the IR photodiode detectors “see” the club head 99 and set a data flag to indicate that the time has been captured. When both data flags are set, the micro-controller 76 stops the timer, stops pulsing the IR sensors 50 B, 50 C and exits the loop.

[0043] The two inner IR sensors 50 B′, 50 C′ on the other array 50 ′ are not used if the golfer is right handed. The micro-controller 76 resets the timer and starts pulsing IR from outer IR sensor 50 A′ on the other array 50 ′ until its photodiode detector “sees” the club head 99 . The reflected signal from the outer IR sensor 50 A′ restarts the timer in the micro-controller 76 and triggers a burst of twenty (20) cycles of 200 KHz sonic energy from the second ultrasonic transmitter 61 ′. The sonic waves quickly reach the club head 99 and are reflected back to the ultrasonic sensor 60 ; the micro-controller 76 stops the timer when the first echo above a set threshold voltage is detected.

[0044] At this point, the micro-controller 76 has captured all the required data, which are then transmitted from the micro-controller 76 to the computer 70 for processing by the software application 40 .

[0045] From a simple physics formula, average velocity equals distance divided by time (v=d/t). With each array 50 , 50 ′, the distance (d) between the outer IR sensors 50 A, 50 A′ and the inner IR sensors 50 B, 50 B′, 50 C, 50 C′, respectively, is two (2) inches. If the club head 99 is perpendicular (“square”) to the target line 92 , both the inner IR sensors 50 B, 50 B′ and 50 C, 50 C′ should “see” the club head 99 at the same time. If the club head 99 is open or closed, then the times that 50 B, 50 B′ (Time 2 ) and 50 C, 50 C′ (Time 3 ) will “see” the club head 99 will be slightly different. The software application 40 calculates the average time (Tavg) by adding T 1 +T 2 and dividing the result by 2 (Tavg=[T 1 +T 2 )/2]). Average club head velocity (Vc) is calculated from the velocity formula as Vc=2.0/Tavg, which can be easily resolved to within one mile per hour.

[0046] If T 1 and T 2 are equal, then club face angle is 0; the club head at impact is perpendicular (square) to the target line. If the times are not equal, then determining club face angle requires two calculations. If T 1 and T 2 are not the same, then a small triangle is formed with one leg (D 1 ) equal to the distance between IR 2 and IR 3 , which is 1.5 inches. The length of the second leg of the triangle (D 2 ) is formed by knowing the average velocity of the club head 99 (Vc) and the difference in time between T 1 and T 2 (T 2 −T 1 ). From simple physics, D 2 =Vc *(T 2 −T 1 ). The hypotenuse of this small triangle forms an angle that represents club face angle, which is calculated as the arc tangent of D 2 /1.5. The analyzer 12 will resolve club face angle to within one degree.

[0047] Determining club head 99 swing path angle also requires two calculations. First, the distance that the club head 99 passes in front of each U/S sensor 60 , 60 ′ is calculated. The speed of sound in air (Vs) is well documented and is primarily a function of ambient air temperature. The micro-controller timer captures the elapsed times required (T 1 and T 2 ) for sonic energy to leave each U/S sensor 60 , 60 ′, reflect from the club head 99 , and be detected as an echo by the same U/S sensor 60 , 60 ′. The distance (D 1 or D 2 ), therefore, is calculated as one-half of the product of Vs×(T 1 or T 2 ), since T 1 and T 2 represent times for the sonic energy to travel out and back to the U/S sensors 60 , 60 ′. Swing Path Angle is calculated by comparing D 1 and D 2 . If the distances are equal, the Swing Path Angle is 0, which means that the club head 99 is traveling parallel to the target line 92 at impact. If D 1 and D 2 are not equal, then a small triangle is formed. One leg of the triangle is the horizontal distance (Dh) between the U/S sensors 60 , 60 ′ (6 inches). The short vertical leg of the triangle (Dv) is the difference between D 1 and D 2 (Dv=D 1 −D 2 ). The hypotenuse of this small triangle forms an angle that represents club swing path angle, which is calculated as the arc tangent of Dv/6. The analyzer will resolve club swing path angle to one degree.

[0048] Club head swing data is collected and transmitted to the user's computer 70 for further processing by the software application 40 . The software application 40 makes several assumptions to calculate trajectory information. First, the software application 40 assumes that the initial ball velocity at impact is a function of available club head 99 energy and the golf ball 90 coefficient of restitution.

[0049] Second, the software application 40 assumes that the club head 99 loft at impact is equivalent to the club head 99 manufactured loft.

[0050] Also, for trajectory calculations, the software application 40 uses a nominal ball spin rate based on the type of golf ball 90 , the club head 99 loft, and the golf ball 90 instantaneous velocity to determine a coefficient of lift and a coefficient of drag for its aerodynamic calculations

[0051] The software application 40 does not determine golf ball 90 roll on the ground; distance measurements are carry distance of the golf ball 90 in the air.

[0052] During use, the software program 40 presents an input page shown in FIG. 8 used to input the user's personal information into the computer. The software program 40 is presents an input page shown in FIG. 9 used to input specifications for the player's golf clubs and environmental condition information shown in FIG. 10 . Once the swing data has been collected and analyzed by the program 40 , the software program 40 then presents the trajectory information on the display as shown on FIG. 11 .

[0053] In compliance with the statute, the invention described herein has been described in language more or less specific as to structural features. It should be understood, however, that the invention is not limited to the specific features shown, since the means and construction shown, is comprised only of the preferred embodiments for putting the invention into effect. The invention is therefore claimed in any of its forms or modifications within the legitimate and valid scope of the amended claims, appropriately interpreted in accordance with the doctrine of equivalents.