On all tennis courts, perhaps the most notable part is the net. In one known example, a tennis net includes two main net posts placed at a pre-determined height (e.g., 107 cm), and positioned a distance (e.g., 91.4 cm) outside the outermost (or doubles) sidelines of a tennis court. The net is typically composed of a woven or plastic netting supported by an upper net cable. The netting hangs from a strong metal cable via a white net tape. The net cable is attached to one post and then to the opposite post, which has a crank that winds the cable so that the net tightens and rises up to the required height and a desired tension.
In the middle of the net, there is a center-strap (also known as a mid-strap) which holds the net down by coming over the top of the net and being fastened to a clasp on the playing surface. This provides greater tension than a crank could practically provide (by pulling down at the mid-point of the net), since cables generally will sag, and provides the defined low part of the net in the center, and at an determinable height, which is an important during play. The result is a semi-V shape running in the top part of the net, where the center strap provides the regulation 91.4 cm height of the net in the middle.
In many tennis tournaments throughout the world, each net can be different. Wimbledon is known for a loose net while the U.S. Open is known for having a tight highly tensioned net. In fact, because both tournaments are outdoors, the net may be taken down as much as several times on any particular day with inclement weather. From tournament to tournament, and court to court, and even from day to day, and hour to hour, there lacks a precise, uniform net tension in tennis. And with this varying net tension, comes varying net heights (as net height is directly correlated to net tension, as explained further below).
When net tension is different, balls that clip the very top of the net (“net tape”) during a rally will dribble over a loose net (resulting in what is called a cheap point), as a net with a looser tension absorbs the forward movement of the ball, allowing balls which hit the tape to roll over to the other side of the net. Conversely, with a tight net, the ball that clips the net tape will either sit up for an easy put away, or bounce out for a loss of the point, as tighter tensions do not absorb the forward pace and either send balls hitting the tape backward or cause the ball to change trajectory and fly out. This causes inconsistency in playing conditions.
Additionally, as mentioned, when net tension is different, the height of the net will be different. This is despite the fact that the net post is a defined height, as is the center-strap (107 cm and 91.4 cm respectively). The net traverses the court typically at 12.8 m in length (or 10.97 m for a singles net post). The net itself weighs approximately 10 kg (alternately approximately twice that for the ATP World Tour nets). Therefore, there will be a measurable sag in the net even when it is cranked up to reach the center-strap 91.4 cm height. The more one cranks thereafter, the tighter the net, thus as the net tension increases, the sag between the net posts/singles sticks and the center-strap will lessen, as the net cable will straighten out while being pulled tighter (resulting in different heights between those two points). This non-measured cranking (done essentially by “feel”) can result in not only an inconsistent net tension but also an inconsistent net height. While the height of a net is the same for players on both sides, a player with more top spin will have an advantage over a player who hits a flatter ball when the net height can vary as much as several millimeters over the most of the playing area of the net (and as much as 1 cm at the midpoint between the singles stick and center-strap where the sag is greatest). Further, players who prefer to hit down the line (as opposed to cross court) will have a lower/higher net height at precisely that part of the net, with potentially different results of any such shot, depending upon the net tension. As the court itself has strictly defined dimensions and measurements in millimeters, as determined by the tennis governing bodies, and thus define the height of the net at any given point by virtue of knowing (and creating) the net tension.
For serves, the current rules call for a “service let,” which is when the ball clips the net and still falls inside the service box. Loose nets will likely result in more lets while tight nets more likely cause the ball to either bounce back, sit up, or fly further and thus out (a “fault”). Professional tennis had recently considered removing the “service let.” Should this still happen in the future, more “aces” will occur with loose nets (as the ball dribbles over to the other side) while tight nets will cause more balls to sit up for easy winners by the opponent or will go fly out for a loss of the point. The result is different depending upon the net tension. This is unacceptable, as the effect can be different on different courts and even change on the same court on the same day when the net often needs to be taken down on outdoor courts during rain, or to change nets during events with different tours (which have different nets). The result is an ever varying net tension and height for virtually each time a net is set up.
There is a need for consistency in net tension across tennis. Disclosed is system and method for measuring the tension of a tennis net, and, alternatively or in addition, for determining if a service let occurs via the measuring of the tension. The disclosed embodiments measure a force exerted by the net on a center-strap or a singles stick. In these embodiments, the measured force provides an accurate reflection of the tension of the net.
The embodiments, examples and alternatives of the preceding paragraphs, the claims, or the following description and drawings, including any of their various aspects or respective individual features, may be taken independently or in any combination. Features described in connection with one embodiment are applicable to the other embodiments, unless such features are incompatible.
The drawings can be described as follows:
The net 12 is supported on opposite sides of the playing area 14 by net posts 16 (
The net 12 is connected to the playing surface 14, in this example, by a center-strap 22. The upper cable 18 exerts an upward force F1 on the center-strap 22 in a direction substantially perpendicular to the length L of the net 12. This is because the net 12 is higher at each end (e.g., the net posts 16 are at 107 cm height) than in the middle, so the center-strap 22 necessarily pulls down upon the net 12, creating the upward force F1. The center-strap 22 resists the force F1 with an equal and opposite force to maintain the net 12 in a normal condition (the pre-determined height of the center-strap 22). The force F1 is resisted by way of the center-strap 22 being connected to the playing surface 14. In one example, the center-strap 22 is connected to the playing surface by a cable 24 attached to a first connecting support 26, which is selectively attachable to a hook 28.
In one example of this disclosure, a scale 30 measures the force F1 exerted by the upper cable 18 on the center-strap. The force F1 is indicative of a tension in the net 12. That is, the higher the tension of the upper cable 18, the higher the force F1 against the center strap 22. As used herein, the term “scale” refers to any force measuring device, including, but not limited to pull scales 32A-32D (
As shown in
As illustrated in
While this disclosure extends to all types of indicators 36, the indicator 36 of
As the upper cable 18 is adjusted, the force F1 will change, and, in turn, so will the height H of the net 12 (between the net post 18 or the singles stick 43, and the center-strap 22) and the overall tension in the upper cable 18. In one example, a loose net may indicate a force F1 of 4.5 kg while a tight net might show a force F1 of 5.8 kg (approximately 44 N and 57 N, respectively). The scale 30 can accurately measure the force F1. In the example of
The measurement can be made with or without singles sticks 43 (
Turning to another embodiment,
In one example, the singles stick 43 is connected to a scale 52 at its base. Seen in detail in
While there are two singles sticks 43 commonly employed in tennis (one on each end of the net), only one stick is generally required to measure the net tension. Further, it will be appreciated that while a standard singles stick is placed 91.4 cm outside the singles sideline, one can also place the device at another point along the net.
Further, because the presence of the center-strap 22 changes the net tension, the measurements taken at the singles sticks 43 will be markedly different if a center-strap 22 is not used, or if used, not at its regulation 91.4 cm height. Thus, the presence or absence of the center-strap 22 should be noted when measuring the force F2. Likewise, the presence or absence of the singles sticks 43 should be noted when measuring the force F1 at the center-strap, as discussed relative to
Turning to
Using any of the above embodiments, one can then duplicate a tension time and again. With no measureable variables, that is, the distance between the net posts (12.8 m), the inelasticity of the steel net cable, the height of the single post (107 cm), and the position of the singles stick (91.4 cm outside the single sideline), and the 91.4 cm height of the net at the center-strap, are all fixed by rule, the net tension will substantially be the exact same in each instance. This measurement can be used each time when putting a net up or can be used to simply test periodically that the net tension has remained the same.
An additional benefit of the system 10 relates to the service let rule. A serve that clips the net 12 but still falls in the service box is called a “let” and is re-played. With the instant disclosure, any ball that comes into contact with the net 12 will change the force (e.g., F1 or F2) caused by tension of the net 12. Such a contact and the resulting change in the force will be picked up by the scale. That is, the contact between the ball and the net changes the force F1, F2 from a normal level to a threshold level indicating that there has been contact between the net 12 and the ball.
The threshold force will be of an extremely short duration, and may create a unique “fingerprint” of a sharp spike (dip/peak). When the threshold force is met, an audible signal (beep) may be triggered, indicating a “let.”
The fingerprint associated with the threshold force will be different than the effect that wind might have. Essentially, the effect of wind on the net tension is more of a constant push than the short-term impact associated with a ball strike. For example, even strong wind gusts have a duration in seconds, while a serve regularly is double or triple that speed, and has an impact duration in milliseconds. Measuring the change of force relative to time (e.g., how fast the force changed from one millisecond to the next one or more) will isolate the signature of a ball impact, allowing it to be identified separately from any wind effect (which will be filtered out). This unique ball strike signature can be used to set the sensitivity for what will be triggered by the threshold force, indicating a “let” ball.
For purposes of illustrating the point, in the embodiment of
The let indication feature may also be useful in matches, such as club matches or recreational matches, which do not typically involve a chair umpire.
In another example of use, the light 80 is always illuminated during play in a first color, such as green, which indicates that the above-mentioned threshold force has not been reached. When the threshold force is reached, the color of the light 80 changes to a second color, such as red. If the second color appears immediately following a serve, the players know that a let occurred. If the second color appears during a rally, the players can simply ignore the light.
While only one side of the scale 30 is illustrated in
It will be appreciated that players could have the ability to activate the let detection function right before a serve, and where the device would automatically de-activate seconds later in order to avoid a possible let signal in a rally. Either or both of the players could activate the device, say, by pressing a button on their person or racket wirelessly connected to the base that activates it right before the serve. While this would require one of the players to remember to activate the device each time before a serve is made, it provides the option of activation of the device only at the time of the serve.
That said, the embodiments of
Although the different examples have the specific components shown in the illustrations, embodiments of this claimed invention are not limited to those particular combinations. It is possible to use some of the components or features from one of the examples in combination with features or components from another one of the examples. Furthermore it is appreciated that distances or features in the drawings may be reduced or exaggerated for illustrative purposes and do not in any way so limit the embodiment shown.
For example, while the forces F1 and F2 are substantially perpendicular to the length L of the net 12, in an alternate embodiment the scale 30 is arranged to measure the tension in the upper cable 18 directly, although this arrangement may lack sensitivity and responsiveness for the required measurements.
As another example, while specific distances such as 107 cm and 91.4 cm have been mentioned above, as currently required by all tennis governing bodies, it should be understood that this disclosure extends to systems including other distances which may include other sports which employs nets. For instance, if the regulations from the tennis governing bodies are followed, the difference between the height at the net posts 16 and the center-strap 22 will be 15.6 cm. However, in some instances the regulations are not followed, resulting in a height difference of about 15.6 cm. As used herein, the term “about” is not a boundaryless term, and should be interpreted in the way one skilled in the art would interpret the term. Similarly, measurements as described in the screen readout are given as examples only and will be different under use.
One of ordinary skill in this art would understand that the above-described embodiments are exemplary and non-limiting. That is, modifications of this disclosure would come within the scope of the claims. Accordingly, the following claims should be studied to determine their true scope and content.
This application is a continuation-in-part of prior U.S. application Ser. No. 14/646,230, filed May 20, 2015, which is a national stage entry of PCT/US2013/072408, filed Nov. 27, 2013. The '408 PCT Application claims the benefit of U.S. Provisional Application No. 61/730,238, filed Nov. 27, 2012, and U.S. Provisional Application No. 61/737,284, filed Dec. 14, 2012. The entirety of each of these disclosures is herein incorporated by reference.
Number | Date | Country | |
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61737284 | Dec 2012 | US | |
61730238 | Nov 2012 | US |
Number | Date | Country | |
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Parent | 14646230 | May 2015 | US |
Child | 15601721 | US |