This application claims priority to European Patent Application No. 18177811.9 filed on Jun. 14, 2018, the entire disclosure of which is hereby incorporated herein by reference.
The invention relates to the field of measurement and analysis of the trajectories of athletes on a sports field, during a sports event.
In recent years, there has been an increasing demand for reliable and objective evaluation of sport specific data. The measurement and analysis of the trajectories of athletes is one possible approach to gain such insights. It allows the assessment of the physical performance and tactical behaviour of athletes. Thus, it can yield helpful feedback for athletes, coaches and referees. Furthermore, spectators can be supplied with additional information about the accomplishments of their idols.
Position tracking systems provide a means for the measurement of athletes' positions and motion trajectories. State-of-the-art systems comprise optical- and radio-based tracking. Optical tracking enables position measurements with a high accuracy and stability, and may provide context information. However, one of the most challenging problems with optical tracking is the correct assignment of tracking data to the respective athletes. On the contrary, radio-based tracking enables explicit assignments of the position data to the athletes. However, a problem of radio-based systems is the quality and the accuracy of positioning.
It is an object of the invention to overcome the weaknesses of the aforementioned tracking approaches, and in particular to provide a method for tracking an athlete (referred to as target) on a sports field, including the correct identification of the target among several athletes being simultaneously tracked, and the correct position data assignment to the target.
Hence, the invention relates to a method according to claim 1.
The term “radio-based” refers to position calculation using distance or angle-of-arrival measurements between tracking sensor and antennas
The method overcomes the drawbacks of optical- and radio-based tracking approaches by combining them. According to the invention, information from the radio-based positioning system and the optical-based positioning system can be fused on a low level, in contrast to some state-of-the-art methods where the positions given by an optical- and a radio-based system may be combined afterwards. The imprecise position of the target given by the radio-based positioning system is used to limit the search space for the optical-based positioning, thus reducing complexity of the calculations. Hence, the method according to the invention has two essential advantages:
Furthermore, the method according to the invention may comprise one or a combination of the characteristics of claims 2 to 10.
Other features and advantages of the present invention will appear more clearly upon reading the following detailed description, made with reference to the annexed drawings, given by way of non-limiting example:
The method according to the invention for calculating the position of a moving athlete—called target—on a sports field requires using a radio-based positioning system RdPS and an optical-based positioning system OpPS.
As illustrated in
In an embodiment, the athletes carry inertial measurement units. This way, additional measurements such as acceleration, inclinations and angular rates can be recorded using the installed set of antennas At1, At2 . . . AtM.
As illustrated in
The method MTH according to the invention comprises the following steps, illustrated in
In a step Est_ApPos, with reference to
In a step Def_ScSpa, with reference to
In a step Dtc_Ath, with reference to
In a step Dtm_AcPos, as illustrated in
In a step Atr_AcPos, the accurate position AcPos is attributed to the target Tgt.
Modern machine learning based recognition algorithms are able to carry out object detection and localization in real time. The main shortcoming of these algorithms is that they are not able to unambiguously identify the respective athlete. In contrast, the position data gathered from radio-based positioning allows for an explicit allocation of the position data of an attached sensor to the target (signals received from multiple sensors can be discriminated by the radio-based positioning system RdPS and the assignment of a sensor to an athlete is defined by the user). Thanks to the method of the invention, accurate positions gathered from optical-based positioning can be assigned to their matching position gathered from radio-based positioning. Thus, an unambiguous allocation of the accurate position measurements to the correct athletes is possible.
In addition, the method MTH may comprises the following steps.
In a step Gen_AdInf, with reference to
In a step Val_AcPos, the additional information AdInf gathered from the optical-based positioning system OpPS and/or from the inertial measurement unit(s) is used to complement and validate the information from the radio-based positioning system. Information about additional objects, such as rackets or sticks, and a detailed analysis of the target may result in a higher position accuracy that are not available only with a radio-based positioning method.
In a step Pr_NxPos, respectively Pr_FtEvt, the additional information AdInf gathered from the optical-based positioning system OpPS and/or from the inertial measurement unit(s) is used to predict a next position NxPos of the target Tgt, respectively a future event FtEvt (for instance, the target is going to use their racket or stick).
Of course, the present invention is not limited to the illustrated example but may be subject to various variants and alterations, which will be apparent to those skilled in the art.
Number | Date | Country | Kind |
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18177811 | Jun 2018 | EP | regional |
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Number | Date | Country | |
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