JP2016073764A - Golf training support device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a golf training support device capable of presenting information on whether or not a golfer captures a golf ball with a core of a golf club to the golfer more accurately.SOLUTION: A golf training support device 10 comprises a Doppler sensor 11, a camera 12, a control part 13, an amplifier 14, a comparator 15, a speed storage part 16, an image storage part 17, a derived result storage part 18, a display device 19, a speaker 20, a switch group 21, and a power supply part 22. When an impact position display mode is selected, the control part 13 displays a photographed image taken when a head collides with a golf ball, that is a photographed image during impact, among photographed images stored in the image storage part 17 on the display device 19, and displays a collision position of the golf ball in the head with an "×" mark.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a golf practice support device.

  As a golf practice support device, for example, there is a speed measuring device that measures the head speed of a golf club or the ball speed of a golf ball using a Doppler sensor. In recent years, there has also been proposed a speed measuring device that derives the meet rate from the measured head speed and the initial velocity of the golf ball and displays the derived result (see, for example, Patent Document 1). Here, the meet rate is a value obtained by dividing the initial speed of the golf ball by the head speed. Displaying the meet rate can be very useful because it can present the golfer with an index as to whether or not the golf ball is accurately captured by the core of the golf club.

JP 2010-22739 A

  However, in the configuration in which the meet rate is derived from the measured head speed and the initial velocity of the golf ball, there may be a case where an accurate meet rate cannot be derived. For example, when a golfer practices a golf ball using golf balls having different restitution coefficients, even if the golf ball collides with the same position on the head of the golf club, a golf ball having a larger restitution coefficient Increases the initial speed of the ball. This means that although the golf ball collides with the same position of the golf club head, a different value is displayed as the meet rate. In order to eliminate such a concern, for example, it is possible to adopt a configuration in which the coefficient of restitution of a golf ball or the like is input to the golf practice support device in advance, but in such a configuration, when using the golf practice support device, There arises a new problem that the preparation is complicated.

  The present invention has been made in view of the circumstances exemplified above, and golf practice support that can more accurately present a golfer with information on whether or not a golf ball is accurately captured by the core of a golf club. The object is to provide an apparatus.

  (1) An imaging unit that captures images at predetermined intervals, an image storage unit that stores an image captured by the imaging unit, and a golf ball installation position based on the image stored in the image storage unit An installation position grasping means, a swing locus grasping means for grasping a swing locus of a golf club based on an image stored in the image storage means, and an image of the golf ball based on an image stored in the image storage means. A movement trajectory grasping means for grasping a movement trajectory; a collision position deriving means for deriving a collision position of the golf ball in the head of the golf club based on grasping results of the swing trajectory grasping means and the movement trajectory grasping means; And a notifying unit for notifying the derivation result of the collision position deriving means.

  According to the golf practice assistance device, the collision position of the golf ball at the head of the golf club is derived based on the swing locus of the golf club and the movement locus of the golf ball, and the derivation result is notified to the notification unit. With such a configuration, it becomes possible to present to the golfer which position on the golf club head the golf ball collided, and information on whether or not the golf ball is accurately captured by the core of the golf club, It becomes possible to present it to the golfer more accurately.

  Note that “notifying the derivation result of the collision position deriving means” is not limited to the configuration in which the derivation result is necessarily notified when the collision position of the golf ball in the golf club head is derived, and a predetermined operation is performed by the golfer. In such a case, the derivation result is notified. As a specific configuration of the notification unit, a configuration including at least one of a display unit that displays a derivation result and an output unit that outputs the derivation result as a voice is given as a representative example.

  (2) In addition to the configuration described in claim 1, a Doppler sensor that outputs a Doppler signal, and a head speed deriving unit that sequentially derives the speed of the head based on the Doppler signal output by the Doppler sensor. And derivation result storage means for storing the derivation result of the head speed derivation means in association with the image stored in the image storage means.

  According to this golf practice assistance device, the speed of the head of the golf club is sequentially derived, and the derivation result is stored in association with the image stored in the image storage means. With this configuration, it is possible to store the speed when the head collides with the golf ball, and it is possible to provide useful information to a golfer or the like having a low skill level. For example, if the head does not collide with the golf ball at the timing when the golf club head reaches the maximum speed, the event is notified, or the rate at which the head collides with the golf ball is used to obtain a more accurate meet rate. This is because it is possible to derive.

  (3) In addition to the configuration described in claim 1, a Doppler sensor that outputs a Doppler signal, and a head speed deriving unit that sequentially derives the speed of the head based on the Doppler signal output by the Doppler sensor. An association means for associating the derivation result storage means for storing the derivation result of the head speed derivation means, the image stored in the image storage means, and the head speed stored in the derivation result storage means It is characterized by comprising.

  According to the golf practice assistance device, the speed of the golf club head is sequentially derived and the derivation result is stored. Then, the image stored in the image storage unit and the head speed stored in the derivation result storage unit are associated with each other. With this configuration, it is possible to store the speed when the head collides with the golf ball, and it is possible to provide useful information to a golfer or the like having a low skill level. For example, if the head does not collide with the golf ball at the timing when the golf club head reaches the maximum speed, the event is notified, or the rate at which the head collides with the golf ball is used to obtain a more accurate meet rate. This is because it is possible to derive.

  (4) In addition to the configuration described in claim 2 or claim 3, a collision speed notifying unit for notifying the speed when the head collides with the golf ball is provided.

  According to the golf practice assistance device, the collision speed notifying unit that notifies the speed when the head collides with the golf ball is provided. By adopting such a configuration, it is possible to provide more useful information to the golfer as compared with the configuration in which only the maximum speed is reported as the head speed. The flight distance of the golf ball varies depending on the speed at which the head collides with the golf ball, not the maximum speed of the head. For this reason, it is assumed that the golfer wants to know the speed when the head collides with the golf ball rather than the maximum speed of the head.

  (5) In addition to the configuration according to any one of claims 1 to 4, a Doppler sensor that outputs a Doppler signal, and a Doppler signal output from the Doppler sensor, based on the installation position of the Doppler sensor. A first speed deriving unit for deriving a speed of the golf ball in a first direction toward the installation position of the golf ball; a first deriving result storing unit for storing a deriving result of the first speed deriving unit; The speed in the moving direction of the golf ball using the correction information deriving means for deriving correction information based on the image stored in the storage means, the correction information, and the deriving result of the first speed deriving means. And a second derivation result storage unit for storing a derivation result of the second speed derivation unit.

  According to the golf practice assistance device, the speed of the golf ball in the first direction from the installation position of the Doppler sensor toward the installation position of the golf ball is derived based on the Doppler signal output by the Doppler sensor. Further, the correction information is derived based on the image stored in the image storage means, and the speed in the moving direction of the golf ball is derived using the correction information and the speed of the golf ball on the virtual line. With this configuration, it is possible to accurately derive the speed in the direction in which the golf ball moves, and to provide accurate information to the golfer. Further, by adopting a configuration in which the correction information is derived based on the image stored in the image storage means, it is possible to facilitate advance preparation such as installation work and input work of the golf practice support device.

  (6) The correction information deriving means derives the speed of the golf ball in a second direction perpendicular to the first direction as the correction information.

  According to the golf practice assistance device, the speed of the golf ball in the second direction perpendicular to the first direction is derived based on the image stored in the image storage unit. In such a configuration, the launch angle of the golf ball can be derived from the speed of the golf ball in the first direction and the speed of the golf ball in the second direction. Therefore, the estimated flight distance of the golf ball can be derived more accurately than the configuration in which the estimated flight distance of the golf ball is derived using a coefficient according to the type of the golf club. Further, in this configuration, it is possible to accurately derive the estimated flight distance of the golf ball without inputting the type of the golf club to the golf practice assistance device, and therefore, it is easy to input the golf practice assistance device. It becomes possible.

  (7) The correction information deriving means derives the speed of the golf ball in a third direction perpendicular to the first direction and the second direction as the correction information.

  According to the golf practice assistance device, the speed of the golf ball in the third direction perpendicular to the first direction and the second direction is derived based on the image stored in the image storage unit. By adopting such a configuration, even when the golf ball does not move on a straight line connecting the installation position of the Doppler sensor and the installation position of the golf ball, the speed in the moving direction of the golf ball is accurately determined. It can be derived. Furthermore, in such a configuration, if the golf practice support device is installed behind the golf ball (that is, the direction opposite to the direction in which the golf ball moves), the installation position is the lowest point of the swing trajectory of the golf club. Even if it is not on the tangent line, the speed in the moving direction of the golf ball can be accurately derived. Therefore, the installation work of the golf practice support device can be facilitated.

  (8) In addition to the configuration according to any one of claims 2 to 7, the imaging unit including the imaging unit and the sensor unit including the Doppler sensor can be separated from each other. The golf practice assistance device according to any one of (1) to (8), wherein a communication unit having a communication function of the same communication protocol is provided in the photographing unit and the sensor unit.

  According to the golf practice support device, the photographing unit having the photographing means and the sensor unit having the Doppler sensor can be separated, and the photographing unit and the sensor unit have the same communication protocol. A communication unit having a communication function is provided. With this configuration, it is possible to photograph the swing form with the photographing unit while measuring the speed of the head with the sensor unit.

  In addition to the structure in any one of Claims 1 thru | or 8, in invention of Claim 9, when the said head collides with the said golf ball based on the grasping | ascertainment result of the said swing locus | trajectory grasping means. A swing direction deriving unit for deriving a swing direction; and a moving direction deriving unit for deriving a direction when the golf ball starts moving based on a grasping result of the moving locus grasping unit. And

  According to this golf practice assistance device, the direction of the swing when the head collides with the golf ball and the direction when the golf ball starts to move are derived. With such a configuration, it is possible to detect whether or not the golf ball is moving straight with respect to the swing trajectory of the golf club.

  (10) Based on the image stored in the image storage means, a center locus grasping means for grasping the locus of the center of the head, a relationship between the grasping result of the center locus grasping means and the installation position of the golf ball. The golf practice support device according to any one of (1) to (9), further comprising: a center trajectory display unit that displays the golf ball as viewed from above.

  According to this golf practice support device, the locus of the center of the head is grasped, and the relationship between the grasping result and the installation position of the golf ball is displayed as a view of the golf ball as viewed from above. By adopting such a configuration, it becomes possible for the golfer to grasp whether the swing locus is inside-out-in, outside-in, or inside-out.

  It is possible to present useful information to the golfer.

It is a figure which shows the example of the utilization state of a golf practice assistance apparatus. It is a figure which shows the structure of a golf practice assistance apparatus. It is a figure which shows the example of the display mode of a display apparatus. It is a figure which shows the example of a picked-up image. It is a figure which shows the example of the derived movement locus | trajectory. It is a figure which shows the example of a picked-up image.

  Hereinafter, embodiments of the golf practice assistance device of the present invention will be described. This golf practice support device has a speed measurement function for measuring the speed when the head of the golf club collides with the golf ball and the speed of the golf ball, and a path for grasping the golf club's swing path and the golf ball's movement path. It has a grasp function.

  FIG. 1 is a diagram illustrating an example of a usage state of the golf practice assistance device 10, and FIG. 2 is a diagram illustrating a configuration of the golf practice assistance device 10.

  The golf practice assistance device 10 is provided with a Doppler sensor 11 and a camera 12. The golf practice assisting apparatus 10 has an antenna opening surface and a camera on the opposite side (hereinafter referred to as “rear side”) of the side where the golf ball 1 flies (hereinafter referred to as “front side”). 12 is installed so as to face the golf ball 1. In general, the impact position of the golf club 2 is in the vicinity of the lowest point of the movement locus 3 of the head 2 a of the golf club 2, and the speed of the head 2 a is maximized at the lowest point of the movement locus 3. For this reason, as shown in FIG. 1A, the golf practice support device 10 is installed on the rear side of the golf ball 1 and on the tangent line 4 of the lowest point of the movement locus 3 of the head 2a. Is most desirable. However, in the golf practice assistance device 10, since the speed of the golf ball can be accurately derived by a trajectory grasping function described later, the installation position of the golf practice assistance device 10 is as described above as shown in FIG. The position may be other than the tangent line 4 (hereinafter referred to as “ideal flying ball line 4”). That is, the golf practice assistance device 10 only needs to be installed on the rear side of the golf ball 1. The distance between the golf ball 1 and the golf practice support device 10 is about 1 m.

  In addition to the Doppler sensor 11 and the camera 12, the golf practice support device 10 includes a control unit 13, an amplifier 14, a comparator 15, a speed storage unit 16, an image storage unit 17, and a derivation result storage unit 18. A display device 19, a speaker 20, a switch group 21, and a power supply unit 22 are provided. The control unit 13 includes a camera 12, an amplifier 14, a comparator 15, a speed storage unit 16, an image storage unit 17, a derivation result storage unit 18, a display device 19, a speaker 20, and a switch group 21. And the power supply unit 22 are connected. The Doppler sensor 11 is connected to an amplifier 14, and the amplifier 14 is connected to a comparator 15 in addition to the control unit 13.

  The control unit 13 includes a CPU, ROM, RAM, flash memory, various peripheral circuits, an interface, and the like. The control unit 13 starts to operate when power is supplied from the power supply unit 22 when the power switch forming the switch group 21 is turned on. The control unit 13 develops the OS and application program recorded in the flash memory on the RAM by the boot loader recorded in the ROM. And the control part 13 performs the various processes shown below by executing OS and application program on RAM, and implement | achieves various functions.

  The Doppler sensor 11 is a microwave Doppler sensor having an output frequency of 24.15 GHz, and an amplifier 14 for amplifying an output signal of the Doppler sensor 11 (a signal corresponding to a movement of 6 mm of the golf club head). It is connected to the. The amplifier 14 is connected to the comparator 15 and the control unit 13. The comparator 15 compares the signal amplified by the amplifier 14 with a reference value, and outputs a Doppler pulse (a high level signal when it is equal to or higher than the reference value and a low level signal when it is smaller than the reference value) to the control unit 13. The analog signal amplified by the amplifier 14 is converted into a digital signal by an A / D converter built in the control unit 13.

  The speed storage unit 16 is for storing the speed of the head 2 a and the speed of the golf ball 1 derived by the control unit 13 based on the output signal of the Doppler sensor 11. The speed storage unit 16 may be an internal storage device that cannot be attached or detached, or a slot unit (including a read / write function) for attaching a removable recording medium such as an SD memory card.

  Here, a process performed by the control unit 13 when deriving the speed of the head 2a and the speed of the golf ball 1 based on the output signal of the Doppler sensor 11 will be briefly described.

  When the power is on, the control unit 13 receives from the comparator 15 a Doppler pulse obtained by performing threshold processing on the analog waveform obtained by amplifying the output of the Doppler sensor 11 by the amplifier 14 using the comparator 15. Therefore, the control unit 13 obtains the period of the Doppler pulse using a built-in counter, and derives the speed of the head 2a and the speed of the golf ball 1. Incidentally, the speed of the head 2a accompanying the swing of the golf club 2 gradually increases from the start of the swing, reaches a maximum before and after colliding with the golf ball 1, and then gradually decreases. On the other hand, since the golf ball 1 remains stopped until it collides with the head 2a, the speed becomes 0, and a predetermined speed is generated by being hit with the head 2a. There is a deviation between the peak of the speed change of the head 2a and the peak of the speed change of the golf ball 1 (the peak of the speed of the golf ball 1 occurs with a delay). Therefore, since two speed peaks occur, the respective speeds of the head 2a and the golf ball 1 can be derived. Since a specific derivation method is a known technique, a description thereof will be omitted.

  When the period of the output signal of the Doppler sensor 11 becomes a periodic pattern corresponding to the swing of the golf club 2, the control unit 13 determines that the swing has started. Then, the control unit 13 sequentially stores the derived speed and the time at that time in the speed storage unit 16 until about 5 seconds elapse after it is determined that the swing is started. That is, when the power is on, the control unit 13 sequentially derives the speed based on the input Doppler pulse, while the speed storage unit 16 stores the predetermined period after determining that the swing has started. Only a predetermined number of speeds derived in the above are stored. With this configuration, the storage capacity of the speed storage unit 16 can be reduced.

  The speed derived based on the Doppler pulse is the speed on the virtual axis 5 that connects the golf practice assistance device 10 and the installation position of the golf ball 1. In the installation state shown in FIG. 1A, the virtual axis 5 and the ideal flying ball line 4 coincide with each other, and in the installation state shown in FIG. 1B, the virtual axis 5 and the ideal flying ball line 4 are shifted.

  The speed of the golf ball 1 is not derived based on the Doppler pulse as described above. For example, a signal output from the amplifier 14 (a signal obtained by amplifying the Doppler signal output by the Doppler sensor 11) is used. The A / D converted data may be separately stored in a memory, and may be derived by performing frequency spectrum analysis (for example, fast Fourier transform (FFT)) on the A / D converted data stored in the memory. The golf ball 1 is small and far from the head 2a. Even in the case of an input signal having a disadvantageous S / N ratio due to a small reflected wave due to a small reflected wave, the FFT disperses the noise component over the entire frequency by frequency decomposition, and the signal component is extracted as a line spectrum. A sufficient signal-to-noise ratio for analysis can be ensured.

  The camera 12 is a high-speed camera that can capture 1000 still images per second. In the golf practice assistance device 10, a camera with a high frame rate is used to derive the collision position of the golf ball 1 against the head 2 a based on the captured image. The camera 12 is provided in the golf practice assistance device 10 so that the direction in which the camera 12 captures a still image is the same as the direction in which the Doppler sensor 11 outputs a microwave.

  The image storage unit 17 is for storing still images taken by the camera 12. The image storage unit 17 may be an internal storage device that is not removable, or may be a slot portion (including a read / write function) for mounting a removable recording medium such as an SD memory card. Further, it may be integrated with the speed storage unit 16.

  The camera 12 captures a still image when the power is on. The photographed image is temporarily stored in a predetermined memory of the control unit 13 together with the photographing time. Specifically, the shot image and the shooting time are sequentially stored from the minimum address of the predetermined memory to the maximum address, and when the shot image and the shooting time are stored at the maximum address, overwriting is sequentially performed from the minimum address. Done. When it is determined that the swing is started based on the Doppler pulse, the control unit 13 displays the captured image and the captured time stored in the predetermined memory until about 5 seconds elapse after the determination. 17 stored. At this time, the image storage unit 17 stores in the predetermined memory immediately before about 5 seconds have elapsed since the determination from the captured image and the recording time stored in the predetermined memory about 1 second before the determination. The captured image and the shooting time are sequentially stored. That is, in the predetermined memory of the control unit 13, when the power is on, the captured image and the captured time are sequentially stored, whereas the image storage unit 17 stores the captured image and the captured image for about 6 seconds including when the swing starts. Only the shooting time is stored.

  The display device 19 is formed by an LCD, an organic EL display, or the like. In addition to the power switch, the switch group 21 is formed by a changeover switch for switching a display mode displayed on the display device 19, an operation switch for giving various instructions, and the like. In addition, a touch panel may be provided in the display device 19 and the touch panel may be used as a changeover switch or an operation switch. The power supply unit 22 may be a primary battery such as a dry battery, or a rechargeable secondary battery such as a rechargeable battery.

  The derivation result storage unit 18 is for storing various information derived by the control unit 13 based on information stored in the speed storage unit 16 and the image storage unit 17. The derivation result storage unit 18 may be an internal storage device that cannot be attached or detached, or a slot unit (including a read / write function) for attaching a removable recording medium such as an SD memory card. Further, the speed storage unit 16 and the image storage unit 17 may be integrated.

  In the golf practice support device 10, a continuous playback mode for continuously displaying images stored in the image storage unit 17, an impact position display mode for displaying which position of the head 2 a the golf ball 1 has collided with, and ideal flight And a swing trajectory display mode for displaying the movement trajectory 3 of the head 2a with respect to the spherical line 4, and the information displayed on the display device 19 can be switched by operating the changeover switch.

  When the impact position display mode is selected, the control unit 13 shoots when the head 2a collides with the golf ball 1 among the captured images stored in the image storage unit 17, as shown in FIG. An image, that is, a captured image at the time of impact is displayed on the display device 19, and the collision position of the golf ball 1 on the head 2 a is displayed with an “x” mark. In addition, the control unit 13 displays on the display device 19 the speed of the head 2a at the time of capturing the captured image, that is, the speed of the head 2a at the time of impact and the speed of the golf ball 1.

  When the swing trajectory display mode is selected, the control unit 13, as shown in FIGS. 3B to 3D, schematically shows the golf ball 1 and the golf club 2 viewed from above, and the ideal flying ball line. 4 is displayed on the display device 19, and the movement locus 3 of the head 2 a is displayed on the display device 19.

  Here, various processes performed when the control unit 13 displays the various information will be described.

  When about 5 seconds have elapsed since it was determined that the swing has started, the control unit 13 executes analysis processing using the captured image stored in the image storage unit 17.

  Prior to the description of the analysis processing, each captured image stored in the image storage unit 17 will be described. The image storage unit 17 stores a captured image of 6 seconds thereafter from 1 second before the swing is started. Before the swing is started, as shown in FIG. 4A, a photographed image in which the whole or a part of the golf ball 1 is hidden by the head 2a is stored. When the swing is started, captured images are sequentially stored in which the head 2a moves out of the imaging range in accordance with the backswing. When the head 2a moves out of the imaging range, As shown in 4 (b), a photographed image obtained by photographing the entire golf ball 1 is stored. Thereafter, the captured images obtained by capturing the head 2a moving toward the golf ball 1 along with the downswing are sequentially stored, and the golf ball 1 is partially hidden by the head 2a as the impact approaches. Images are stored. In the event of an impact, as shown in FIG. 4C, a captured image in which the entire golf ball 1 is hidden by the head 2a is stored. After the impact, when the head 2a that moves outside the shooting range with the follow swing and the golf ball 1 that has started flying are sequentially stored, the head 2a moves outside the shooting range As shown in FIG. 4D, a photographed image obtained by photographing only the flying golf ball 1 is stored.

  In the analysis process, the control unit 13 specifies the golf ball 1 and the golf club 2 by pattern matching or the like, and specifies the center position of the golf ball 1 and the center position of the head 2a. Then, the control unit 13 motion-detects the center position of the golf ball 1 and the center position of the head 2a from each captured image. The control unit 13 derives the initial position of the center of the golf ball 1, the movement trajectory of the center of the golf ball 1, and the movement trajectory of the center of the head 2a based on the result of the motion detection, and derives these derivation results. Store in the storage unit 18. The initial position of the center of the golf ball 1 can be derived from the captured image of FIG. 4B or the like because the golf ball 1 does not move before impact. The movement locus of the center of the golf ball 1 can be derived from the position of the center of the golf ball 1 specified from each captured image. The movement trajectory of the center of the head 2a can be derived from the position of the center of the head 2a identified from each captured image. For example, the movement trajectory 3 of the center of the head 2a can be obtained by connecting the specified center position of the head 2a ("x" in the figure) as shown in FIG. The movement trajectory of the center of 1 can be obtained by connecting the specified center position of the golf ball 1 ("x" in the figure) as shown in FIG.

  Thereafter, the control unit 13 identifies a captured image at the time of impact from each captured image, and stores an address where the identified captured image is stored in the derivation result storage unit 18. As described above, the entire golf ball 1 is photographed during the backswing, gradually disappears from the photographed image as the impact approaches, and completely disappears from the photographed image during the impact. Be photographed. For this reason, the control unit 13 cannot identify the golf ball 1 at least at the time of impact. Therefore, the control unit 13 specifies the first captured image in which the golf ball 1 has completely disappeared among the captured images after the entire golf ball 1 is captured as the captured image at the time of impact. To do. Further, when the captured image at the time of impact is specified, the control unit 13 derives the collision angle of the head 2a with respect to the golf ball 1 at the time of impact, that is, the direction of the vector that the center of the head 2a has at the time of impact. The orientation of the vector at the center of the head 2a is determined by the position of the center of the head 2a in the captured image at the time of impact, the position of the center of the head 2a in the captured image captured immediately thereafter (that is, one frame later), and the Doppler. It can be derived from the speed of the head 2a at the time of impact derived based on the pulse.

  When the address at which the identified captured image is stored and the collision angle of the head 2a with the golf ball 1 at the time of impact are stored in the derivation result storage unit 18, the ball speed derivation process is started. As described above, the speed of the golf ball 1 derived based on the Doppler pulse is the speed on the virtual axis 5 that connects the golf practice support device 10 and the installation position of the golf ball 1. Therefore, when the golf ball 1 does not move on the ideal flying ball line 4 in the installation state shown in FIG. 1A, or when the golf ball 1 is on the ideal flying ball line 4 in the installation state shown in FIG. When the golf ball 1 does not move on the virtual axis 5 as in the case where the golf ball 1 is moved, the speed in the moving direction of the golf ball 1 and the speed of the golf ball 1 derived based on the Doppler pulse Therefore, a deviation occurs. Specifically, when the golf ball 1 does not move on the ideal flying ball line 4 in the installation state shown in FIG. 1A, the speed of the golf ball 1 derived based on the Doppler pulse is as follows. It becomes slower than the speed in the direction of movement. Therefore, the speed in the direction in which the golf ball 1 moves is accurately derived by performing the ball speed deriving process.

  In the ball speed derivation process, a virtual axis extending in the horizontal direction (hereinafter referred to as “x-axis”) and a virtual axis perpendicular to the x-axis (hereinafter referred to as “y-axis”) on the captured image. And the speed of the golf ball 1 on the x-axis and the speed of the golf ball 1 on the y-axis using the movement trajectory of the center of the golf ball 1 stored in the derivation result storage unit 18. To derive. Specifically, the golf ball 1 on the x-axis is determined based on the position of the center of the golf ball 1 specified first after the impact and the position of the center of the golf ball 1 specified immediately after that (that is, after one frame). The amount of movement and the amount of movement of the golf ball 1 on the y-axis are derived, and these derivation results are multiplied by the frame rate of the camera 12. A virtual axis 5 connecting the golf practice assistance device 10 and the installation position of the golf ball 1 is an axis orthogonal to the x-axis and the y-axis (hereinafter referred to as “z-axis”). Therefore, the speed in the moving direction of the golf ball 1 is obtained by combining the speed on the x-axis and the y-axis derived based on the captured image and the speed on the z-axis derived based on the Doppler pulse. Can be derived. When the speed in the moving direction of the golf ball 1 is derived, the derived result is stored in the derived result storage unit 18. Incidentally, the derivation result of the initial position of the center of the golf ball 1, the movement locus of the center of the golf ball 1, and the movement locus of the center of the head 2a is a derivation result in the xy plane.

  When the impact position display mode is selected, the captured image of the address stored in the derivation result storage unit 18 is displayed on the display device 19 and the golf ball 1 stored in the derivation result storage unit 18 is displayed. An “x” mark is displayed at a position corresponding to the initial position of the center. Further, the speed derived by the ball speed deriving process is displayed on the display device 19, and the speed of the head 2 a corresponding to the captured image at the address stored in the derivation result storage unit 18 is displayed on the display device 19. To do. As described above, the speed storage unit 16 stores the derived speed and the derived time, and the image storage unit 17 stores the captured image and the captured time. By adopting a configuration in which the time corresponding to each data is stored in the speed storage unit 16 and the image storage unit 17 together, the period for capturing a still image and the period for deriving the speed are not synchronized. However, the captured image and the speed derived based on the Doppler pulse can be related to each other by the time stored in the storage units 16 and 17, and the speed when the head 2a collides with the golf ball 1, that is, The speed of the head 2a at the time of impact can be displayed. More specifically, the control unit 13 specifies a derivation time from the speed storage unit 16 that coincides with or is closest to the shooting time of the captured image at the time of impact, and the speed storage unit at the specified derivation time. The speed stored in 16 is displayed as the speed of the head 2a at the time of impact. In a configuration in which the period for capturing a still image and the period for deriving the speed are synchronized, the time corresponding to each data is not stored in the speed storage unit 16 and the image storage unit 17 together. It is possible to associate the captured image with the derived speed. The n (n is a natural number) captured image stored in the speed storage unit 16 and the n (n is a natural number) stored speed in the image storage unit 17 are captured or derived at the same time. Because.

  When the swing locus display mode is selected, on the xz plane based on the movement locus of the center position of the head 2a stored in the derivation result storage unit 18 and the initial position of the center of the golf ball 1 The movement locus of the center position of the head 2a is derived. Then, a schematic diagram in which the golf ball 1 and the golf club 2 are viewed from above and the ideal flying ball line 4 are displayed on the display device 19, and the movement locus 3 of the center position of the head 2a in the derived xz plane is displayed. Display on the device 19. In addition, drawing data of a schematic diagram of the golf ball 1 and the golf club 2 viewed from above and the ideal flying ball line 4 is stored in the control unit 13 in advance. The drawing data of the golf club 2 may be data imitating a general golf club shape, or may be data obtained by photographing an actual golf club from above. The same applies to the drawing data of the golf ball 1.

  Here, the movement locus of the center position of the head 2a in the xz plane will be described.

  In FIG. 3B, the movement trajectory 3 at the time of backswing or downswing is located inside the ideal flying ball line 4, touches the ideal flying ball line 4 at the time of impact, and then moves again by follow-through. 3 is located inside the ideal flying ball line 4. This means that the head 2a is drawing an inside-out-in path, and when the head 2a has a square face orientation at the time of impact, the golf ball 1 becomes a straight ball.

  In FIG. 3C, the movement locus 3 at the time of backswing or downswing is located outside the ideal flying ball line 4, and the movement locus 3 is located inside the ideal flying ball line 4 in the follow through after the impact. ing. This means that the head 2a is drawing an outside-in trajectory, and the golf ball 1 basically becomes a ball of the sliced ball.

  In FIG. 3D, the movement locus 3 at the time of backswing or downswing is located inside the ideal flying ball line 4, and the movement locus 3 is located outside the ideal flying ball line 4 in the follow-through after the impact. ing. This means that the head 2a is drawing an inside-out path, and the golf ball 1 basically becomes the ball of the hook ball.

  The ball of the golf ball 1 is determined by the movement locus 3 of the center position of the head 2a and the orientation of the face at the time of impact. Therefore, for example, when the golf ball 1 becomes the ball of the hook ball, the golfer confirms the movement locus 3 of the center position of the head 2a in the swing locus display mode so that the head 2a draws an inside-out locus. Therefore, it can be understood whether it became a hook ball because of the impact, or a hook ball because the face was closed at the time of impact. As a result, it is possible to practice such as correcting the swing in the subsequent golf practice.

  According to the embodiment described in detail above, the following excellent effects are obtained.

  In the impact position display mode, a captured image at the time of impact is displayed on the display device 19, and the collision position of the golf ball 1 on the head 2a is represented by “x” marks. With this configuration, it is possible to present to the golfer which position of the head 2a the golf ball 1 has collided with, and information on whether or not the golf ball 1 is accurately captured by the core of the golf club 2 can be obtained. Compared to the configuration presented by the meet rate, more accurate information can be presented to the golfer.

  The speed storage unit 16 stores the derived speed and the derived time, and the image storage unit 17 stores the captured image and the captured time. By adopting a configuration in which the time corresponding to each data is stored in the speed storage unit 16 and the image storage unit 17 together, the period for capturing a still image and the period for deriving the speed are not synchronized. However, the captured image and the speed derived based on the Doppler pulse can be associated with each other by the time stored in the storage units 16 and 17, and the speed of the head 2a at the time of impact can be displayed.

  In the impact position display mode, in addition to the collision position of the golf ball 1 on the head 2a, the speed of the head 2a at the time of impact is displayed. By adopting such a configuration, it is possible to provide more useful information to the golfer as compared with a configuration in which only the highest speed is displayed as the speed of the head 2a. The flight distance of the golf ball 1 varies depending on the speed of the head 2a at the time of impact, not the highest speed of the head 2a. If the golfer is highly skilled, the ratio of the speed of the head 2a at impact matches the maximum speed, but if the golfer is low in skill, the speed of the head 2a at impact does not match the maximum speed. The percentage can be high. For this reason, it is assumed that the golfer wants to know the speed of the head 2a at the time of impact rather than the maximum speed of the head 2a. Therefore, by adopting a configuration in which the speed of the head 2a at the time of impact is displayed instead of the maximum speed of the head 2a, the golfer can efficiently increase the skill level by using the golf practice assistance device 10.

  The speed on the x-axis and the y-axis of the golf ball 1 is derived based on the photographed image, and the speed on the z-axis of the golf ball 1 is derived based on the Doppler pulse, and these are combined to create a golf ball The speed in the direction of movement of 1 was derived. By adopting such a configuration, even when the golf practice support device 10 is installed on the ideal flying ball line 4, the golf ball 1 does not move on the ideal flying ball line (that is, does not fly straight). The speed in the moving direction of the golf ball 1 can be accurately derived, and accurate information can be provided to the golfer. In addition, even when the golf practice support device 10 is not installed on the ideal flying ball line 4, the speed in the moving direction of the golf ball 1 can be accurately derived. The work can be facilitated.

  In the swing trajectory display mode, a schematic diagram of the golf ball 1 and the golf club 2 viewed from above and the ideal flying ball line 4 are displayed on the display device 19, and the movement trajectory 3 of the head 2 a is displayed on the display device 19. The configuration is as shown. By adopting such a configuration, it becomes possible for the golfer to grasp whether the swing trajectory was inside-out-in, outside-in, or inside-out, and to practice such as correcting the swing in the subsequent golf practice. Is possible.

  In addition, it is not limited to the description content of each embodiment mentioned above, For example, you may implement as follows.

  (1) In the above embodiment, the camera 12 and the Doppler sensor 11 are integrally provided. However, the camera 12 and the Doppler sensor 11 may be provided separately. That is, it is good also as a structure which can isolate | separate the imaging | photography unit which has an imaging | photography function, and the sensor unit which has a Doppler sensor.

  At this time, a control unit for realizing the above-described various functions is provided in at least one of the photographing unit and the sensor unit, and a communication unit having a communication function of the same communication protocol is provided in each of the photographing unit and the sensor unit. In such a configuration, for example, when the photographing unit is installed at a position directly facing the golfer and the sensor unit is installed behind the golf ball 1, the speed in the moving direction of the golf ball 1 cannot be derived, but the golfer's swing The speed on the z-axis line of the head 2a and the golf ball 1 can be derived while photographing the form. Therefore, by displaying these on the display device 19, the speed of the swing form and the head 2a can be confirmed simultaneously.

  (2) In the above embodiment, the function of displaying the collision position of the golf ball 1 in the head 2a, the function of displaying the speed of the head 2a, and the function of displaying the speed in the moving direction of the golf ball 1 However, the present invention is not limited to the configuration having all these functions, and may be any configuration having at least one function.

  (3) In the above embodiment, the golfer 1 is notified by displaying various information such as the collision position of the golf ball 1 in the head 2 a on the display device 19. It is good also as a structure which alert | reports to a golfer. It goes without saying that the display device 19 and the sound output from the speaker 20 may be performed together.

  (4) In the above embodiment, the speed of the head 2a at the time of impact and the speed of the golf ball 1 are displayed in the impact position display mode. However, these speeds are displayed in a display mode different from the impact position display mode. It is good also as composition to do.

  (5) Although the above embodiment has been described as a configuration in which the speed of the head 2a and the speed of the golf ball 1 are derived, only the speed of the head 2a is derived when the golfer swings. Not too long.

  (6) In the above embodiment, the information corresponding to the image storage unit 17 and the speed storage unit 16 is stored when it is determined that the swing is started. However, when the measurement start button is operated, etc. The information corresponding to the image storage unit 17 and the speed storage unit 16 may be stored when a predetermined operation is performed.

  (7) In the above embodiment, the derived speed is sequentially stored in the speed storage unit 16 until about 5 seconds elapse after it is determined that the swing is started. The time for storing the speed in the speed storage unit 16 is arbitrary. Alternatively, the storage may be terminated when a predetermined operation such as a measurement end button is operated. The same applies to the image storage unit 17.

  (8) In the above embodiment, the speed of the golf ball 1 on the x-axis and the y-axis is derived based on the captured image, but only the speed of the golf ball 1 on the x-axis is derived. It is good also as a structure. In such a configuration, when a golf practice support device is installed on the ideal flying ball line 4 but the golf ball 1 moves out of the ideal flying ball line, the accurate speed of the golf ball 1 is derived. Can not be. However, when compared with a golf practice support device that derives and displays the speed of the golf ball 1 on the z-axis based on the Doppler pulse, the speed of the golf ball 1 on the x-axis can be considered. The accurate speed of the golf ball 1 can be displayed.

  (9) In the above embodiment, the speed derived from the Doppler pulse is used to correct the speed of the golf ball 1 derived from the speed derived from the captured image. However, the speed is derived from the Doppler pulse. It may be configured to correct the speed of the head 2a.

  (10) In the above embodiment, in the swing trajectory display mode, the schematic diagram in which the golf ball 1 and the golf club 2 are viewed from above and the ideal flying ball line 4 are displayed on the display device 19 and derived xz. The movement locus 3 of the center position of the head 2a in the plane is configured to be displayed on the display device 19. However, the golf club 2 is moved along the movement locus 3 until the golf club 2 collides with the golf ball 1. It may be configured to display an animation. Further, the subsequent movement of the golf club 2 may be displayed as an animation, and after the collision between the golf club 2 and the golf ball 1, an animation display for moving the golf ball 1 faster than the golf club 2 is displayed. Also good.

  (11) In the above embodiment, when it is determined that the swing is started, the data corresponding to the speed storage unit 16 and the image storage unit 17 is stored. However, the configuration is changed.

  The control unit 13 determines whether or not the golf ball 1 exists within the shooting range by pattern matching or the like. When the golf ball 1 exists, the position of the center of the golf ball 1 is motion detected. If the position of the center of the golf ball 1 has not been displaced for a predetermined time, it is determined that the golf ball 1 has been installed, and the position at this time is stored in the derivation result storage unit 18 as the initial position of the center of the golf ball 1. . Further, when it is determined that the golf ball 1 is installed, data and time corresponding to the speed storage unit 16 and the image storage unit 17 are stored until an end condition such as the elapse of a predetermined time is satisfied.

  Each captured image stored in the image storage unit 17 in this configuration will be described.

  When the golf ball 1 is installed, a photographed image obtained by photographing the entire golf ball 1 is stored as shown in FIG. When the golf ball 1 is installed or the golfer himself installs the golf ball 1, the golfer places the head 2 a behind the golf ball 1 to hit the golf ball 1. As a result, until the backswing is started, as shown in FIG. 6B, a photographed image in which the whole or a part of the golf ball 1 is hidden by the head 2a is stored. When the backswing is started, the captured images are sequentially stored so that the head 2a moves out of the imaging range. When the head 2a moves out of the imaging range, FIG. 6 (c) As shown in FIG. 2, a photographed image obtained by photographing the entire golf ball 1 is stored again. Thereafter, photographed images of the head 2a moving toward the golf ball 1 with a downswing are sequentially stored, and part of the golf ball 1 is hidden behind the head 2a as the impact approaches. A photographed image is stored, and a photographed image in which the entire golf ball 1 is hidden by the head 2a is stored again as shown in FIG. After the impact, when the head 2a that moves outside the shooting range with the follow swing and the golf ball 1 that has started flying are sequentially stored, the head 2a moves outside the shooting range As shown in FIG. 6D, a photographed image obtained by photographing only the flying golf ball 1 is stored.

  As described above, even when it is configured to store data corresponding to the speed storage unit 16 and the image storage unit 17 when it is determined that the golf ball 1 is installed, the swing start is performed as in the above embodiment. It is possible to specify the first captured image in which the golf ball 1 is completely lost later as the captured image at the time of impact.

  (12) In the above embodiment, the configuration is such that the captured image at the time of impact is specified from the captured image stored in the image storage unit 17, but the captured image at the time of impact is determined from the speed stored in the speed storage unit 17. It is also possible to use a combination of the captured image stored in the image storage unit 17 and the speed stored in the speed storage unit 17 to specify the captured image at the time of impact. As a configuration for specifying the shot image at the time of impact from the speed stored in the speed storage unit 17, the shot image shot at the time when the head 2a reaches the highest speed is specified as the shot image at the time of impact. The configuration is given as a representative example.

  Further, the time difference between the time when the peak of speed change of the head 2a (that is, the highest speed) is derived and the time when the peak of speed change of the golf ball 1 (that is, the initial speed) is derived is calculated based on the time deviation. The time may be specified, and the corresponding captured image may be specified as the captured image at the time of impact. More specifically, the control unit 13 stores a reference deviation width in advance. The reference deviation width refers to the time when the maximum speed of the head 2a is derived when the head 2a collides with the golf ball 1 at the timing when the head 2a reaches the maximum speed, and the time when the initial speed of the golf ball 1 is derived. , The deviation width. As described above, the maximum speed of the head 2a is derived at the lowest point of the movement locus 3 of the head 2a. For this reason, when the impact position in the movement locus 3 of the head 2a is behind the lowest point, the time when the highest speed of the head 2a is derived and the time when the initial speed of the golf ball 1 is derived When the deviation width becomes larger than the reference deviation width and the impact position on the movement locus 3 of the head 2a is in front of the lowest point, the time when the highest speed of the head 2a is derived and the initial speed of the golf ball 1 The deviation width from the time at which is derived is smaller than the reference deviation width. Therefore, when the deviation width derived from each time stored in the speed storage section 16 (hereinafter referred to as “derived deviation width”) matches the reference deviation width, the control section 13 sets the maximum speed of the head 2a. The derived time is identified as the time of impact. When the derived deviation width is smaller than the reference deviation width, the difference between the reference deviation width and the derived deviation width is derived, and the time obtained by adding the derivation result to the time when the maximum speed of the head 2a is derived is the time at impact. Is specified. When the derived deviation width is larger than the reference deviation width, the difference between the derived deviation width and the reference deviation width is derived, and the time obtained by subtracting the derivation result from the time when the maximum speed of the head 2a is derived is the time at impact. Is specified.

  (13) In the above-described embodiment, in the impact position display mode, the collision position of the golf ball 1 is displayed with the “x” mark, but the display mode of the collision position is not limited to such a configuration. It is good also as a structure which specifies and displays the outline of the golf ball 1 from the picked-up image shown in FIG.4 (b).

  (14) Using the information stored in the speed storage unit 16, the information stored in the image storage unit 17, and the information stored in the derivation result storage unit 18 to realize other functions. Is also possible.

  For example, the meet rate is derived using the speed in the moving direction of the golf ball 1 and the speed when the head 2a collides with the golf ball 1, and the derived result is displayed. By deriving the meet rate using each of the above speeds, the speed of the golf ball 1 and the maximum speed of the head 2a are derived based on the Doppler pulse, and compared with the configuration in which the meet rate is derived using these. A more accurate meet rate can be derived.

  For example, the estimated flight distance is derived from the speed in the moving direction of the golf ball 1 and the derived result is displayed. The estimated flight distance can be estimated by multiplying the initial speed of the golf ball 1 by 4. A golf ball derived from a Doppler sensor by inputting the type of the golf club used for golf practice before the measurement into a speed measuring device that measures the speed of the head and the speed of the golf ball using a Doppler sensor. The estimated flight distance may be derived and displayed based on the speed and the coefficient (specifically the launch angle) corresponding to the type of the input golf club. However, in such a configuration, since it is necessary to input the type of golf club used by the golfer for golf practice before measurement, the preparation is complicated. In addition, when a golfer makes a top impact or a duffy impact, the golf ball moves at a launch angle that does not correspond to the type of golf club, so an accurate estimated flight distance is derived. Can not do. On the other hand, the speed on the x-axis and the y-axis of the golf ball 1 is derived based on the photographed image, and the speed on the z-axis of the golf ball 1 is derived based on the Doppler pulse, and these are synthesized. In the present configuration in which the speed in the moving direction of the golf ball 1 is derived, the speed in the moving direction of the golf ball 1 can be accurately derived regardless of the type of the golf club. Further, since the launch angle can be derived from the speed on each axis regardless of the type of the golf club, the golfer does not need to input the type of the golf club before the measurement. Therefore, it is possible to derive a more accurate estimated flight distance of the golf ball 1 while facilitating advance preparation.

  For example, when the speed when the head 2a collides with the golf ball 1 and the maximum speed of the head 2a are different, these speeds are displayed together. Instead of this or in addition, when the speed when the head 2a collides with the golf ball 1 matches the maximum speed of the head 2a, a predetermined notification is made. In such a configuration, it is possible to determine whether or not the timing of impact is appropriate.

  For example, it is determined whether or not the golf ball 1 flies straight based on the movement locus of the center position of the head 2a and the movement locus of the center of the golf ball 1 and performs a predetermined notification when the golf ball 1 flies straight. And

  (15) The speed derived based on the Doppler pulse, the captured image, and the association information such as the time for associating these can be extracted to the outside of the golf practice support device 10, and a predetermined analysis program is provided. A configuration may be adopted in which the collision position of the golf ball 1 on the head 2a is derived in an external device such as a stored personal computer.

  (16) It is good also as a structure which provides the light output part which outputs (irradiates) light to the golf ball 1 and the golf club 2. FIG.

  For example, the light output unit may be configured to output light in the same direction as the shooting direction of the camera 12. In addition, for example, when infrared light is used as light, it is particularly good because it enables photographing even in a dark environment and does not hinder golf practice.

  Whether the light is output from the light output unit may be controlled by the control unit 13. For example, when the golf ball 1 is not reflected in the captured image, when the captured image is completely dark (black), or when the golf ball 1 cannot be distinguished from the floor surface by backlight, When it is a captured image in which the motion detection of 1 is difficult, it is preferable to perform control to output light from the light output unit.

  Although it is good also as a structure which always outputs light from a light output part, the operation time by a battery can be extended by controlling whether light is output.

  For example, when an IR / LED is connected to the control unit 13 and the captured image of the camera 12 is an output at a level at which the golf ball 1 is not reflected, control to turn on the IR / LED may be performed.

DESCRIPTION OF SYMBOLS 10 ... Golf practice assistance apparatus 11 ... Doppler sensor 12 ... Camera 13 ... Control part 14 ... Amplifier 15 ... Comparator 16 ... Speed memory | storage part 17 ... Image memory | storage part 18 ... Derived result memory | storage part 19 ... Display apparatus 20 ... Speaker 21 ... Switch Group 22 ... power supply

Claims (5)

An impact position display mode having a function of displaying at which position of the head the golf ball collided;
A swing trajectory display mode having a function of displaying the movement trajectory of the head with respect to the ideal flying ball line;
A golf practice support device comprising a switching function for switching between the impact position display mode and the swing trajectory display mode. In the impact position display mode, the captured image at the time of impact among the captured images stored in the image storage unit is displayed on the display means, and the collision position of the golf ball on the head is displayed with a mark. The golf practice support device according to claim 1, further comprising a function of causing the display means to display the speed of the head at the time of impact and the speed of the golf ball. The swing trajectory display mode has a function of displaying a schematic view of a golf ball and a golf club viewed from above and the ideal flying ball line on the display means and displaying the movement trajectory of the head on the display means. The golf practice assistance device according to claim 1, wherein: It has a continuous playback mode for continuously displaying images stored in the image storage unit,
The golf support apparatus according to any one of claims 1 to 3, wherein the switching function includes a function of switching between the impact position display mode, the swing locus display mode, and the continuous reproduction mode. The program for making a computer implement | achieve the function of the golf assistance apparatus in any one of Claim 1 to 4.

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