Method and apparatus for radar measurement of ball in play
First Claim
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1. A method of precisely measuring the positions of a generally symmetrical object in motion, in a predefined three-dimensional region, comprising the steps of:
- (a) transmitting multiple radar signals from each of first, second, and third spaced antenna devices, respectively, into the three-dimensional region, the object reflecting multiple return signals corresponding to the multiple radar signals, respectively;
(b) sensing the return signals by means of receivers connected to the first, second, and third antenna devices, respectively;
(c) comparing the return signals with the corresponding transmitted multiple radar signals, respectively, to determine phases of the return signals relative to phases of the corresponding transmitted multiple radar signals, respectively, to obtain ambiguous representations of first, second, and third ranges of the object relative to the first, second, and third antenna devices, respectively;
(d) removing ambiguities of the first, second, and third ranges using modular arithmetic to obtain first, second, and third less-ambiguous ranges or unambiguous ranges of the object relative to the first, second, and third antenna devices, respectively;
(e) if the ambiguities removed in step (d) do not result in an unambiguous region sufficiently large to define first, second, and third unambiguous ranges of the object, using first, second, and third time of arrival range information and/or a priori information in conjunction with the first, second, and third less ambiguous ranges to obtain the first, second, and third unambiguous ranges of the object; and
(f) computing three-dimensional coordinates of the object using the first, second, and third unambiguous ranges and the coordinates of the first, second, and third antenna devices.
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Abstract
A system for continuously and precisely measuring the positions of a generally symmetrical object, e.g., a tennis ball, in motion in a predefined three-dimensional region, e.g., a tennis court, which transmits multiple radar signals from first, second, and third, spaced antenna devices, respectively, into the three-dimensional region. Multiple return signals are sensed and are compared with the transmitted signals to determine the phases of the return signals, to thereby obtain ambiguous ranges of the object. Ambiguities are removed by using the Chinese Remainder Theorem to obtain less-ambiguous ranges. Time-of-arrival range information is used in conjuction with the less-ambiguous ranges to provide unambiguous ranges over the range of interest. The unambiguous ranges are used to compute three-dimensional coordinates of the object that are accurate to within approximately 0.1 inches. A mathematical model defining boundaries of the three-dimensional region is completed by placing signal reflector devices on various boundary points of the three-dimensional region, and transmitting the radar signals when the object is not in the three-dimensional region. Coordinates of a projected trajectory are computed and compared with the actual coordinatres of the object, and certain characteristics are computed therefrom. Calibration of the system is maintained by placing signal reflector devices at various fixed locations within the region of interest and the return signals are processed to obtain an initial survey of the region and then to periodically resurvey the region.
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Citations
14 Claims
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1. A method of precisely measuring the positions of a generally symmetrical object in motion, in a predefined three-dimensional region, comprising the steps of:
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(a) transmitting multiple radar signals from each of first, second, and third spaced antenna devices, respectively, into the three-dimensional region, the object reflecting multiple return signals corresponding to the multiple radar signals, respectively; (b) sensing the return signals by means of receivers connected to the first, second, and third antenna devices, respectively; (c) comparing the return signals with the corresponding transmitted multiple radar signals, respectively, to determine phases of the return signals relative to phases of the corresponding transmitted multiple radar signals, respectively, to obtain ambiguous representations of first, second, and third ranges of the object relative to the first, second, and third antenna devices, respectively; (d) removing ambiguities of the first, second, and third ranges using modular arithmetic to obtain first, second, and third less-ambiguous ranges or unambiguous ranges of the object relative to the first, second, and third antenna devices, respectively; (e) if the ambiguities removed in step (d) do not result in an unambiguous region sufficiently large to define first, second, and third unambiguous ranges of the object, using first, second, and third time of arrival range information and/or a priori information in conjunction with the first, second, and third less ambiguous ranges to obtain the first, second, and third unambiguous ranges of the object; and (f) computing three-dimensional coordinates of the object using the first, second, and third unambiguous ranges and the coordinates of the first, second, and third antenna devices. - View Dependent Claims (2, 3, 4, 5)
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6. A method of precisely measuring the three-dimensional positions of a set of at least four spaced antenna devices and a set of spaced signal reflectors at various fixed positions relative to a three-dimensional region of interest, comprising the steps of:
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(a) taking the position of one of the antenna devices or signal reflectors as the origin of the three dimensional coordinate system and taking the line between this origin and one other antenna device or corner reflector as one of a plurality of coordinate axes; (b) transmitting multiple radar signals from each of the spaced antenna devices, respectively, into the three-dimensional region containing the set of signal reflectors, each signal reflector reflecting multiple return signals corresponding to the multiple radar signals, respectively; (c) sensing the return signals of each signal reflector by means of receivers connected to each of the set of antenna devices, respectively; (d) comparing the return signals from each of the signal reflectors with the corresponding transmitted multiple radar signals, respectively, to determine phases of the return signals relative to phases of the corresponding transmitted multiple radar signals, respectively, to obtain ambiguous representations of the range of each antenna device relative to each signal reflector; (e) removing ambiguities of each of the set of ranges using modular arithmetic to obtain a less-ambiguous range or unambiguous range from each of the set of antenna devices to each of the set of signal reflectors; (f) if the ambiguities removed in step (e) do not result in an unambiguous region sufficiently large to define the above set of unambiguous ranges, using time-of-arrival range information from each antenna device to each signal reflector and/or a priori information in conjunction with the less-ambiguous range from each antenna device to each signal reflector to obtain the unambiguous range from each antenna device to each signal reflector; (g) obtaining crude three dimensional coordinates of each of all antenna devices and all signal reflectors from a priori information, and computing, using the unambiguous ranges and the crude three-dimensional coordinates, more precise three-dimensional coordinates of each antenna device and each signal reflector; (h) periodically repeating the sequence of steps (b)-(g) to update all the three dimensional positions as ambient conditions change.
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7. A method for obtaining a mathematical-boundary-model of a three-dimensional region of interest, comprising the steps of:
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(a) placing signal reflectors, either simultaneously or in sequence, on various boundary points of the region; (b) transmitting multiple radar signals from each of a set of at least three spaced antenna devices, respectively, into the three-dimensional region containing the signal reflectors, each signal reflector reflecting multiple return signals corresponding to the multiple radar signals, respectively; (c) sensing the return signals of each signal reflector by means of receivers connected to each of the set of antenna devices, respectively; (d) comparing the return signals from each of the signal reflectors with the corresponding transmitted multiple radar signals, respectively, to determine phases of the return signals relative to phases of the corresponding transmitted multiple radar signals, respectively, to obtain ambiguous representations of the range of each antenna device relative to each signal reflector; (e) removing ambiguities of each of the set of ranges using modular arithmetic to obtain a less-ambiguous range or unambiguous range from each of the set of antenna devices to each of the set of signal reflectors; (f) if the ambiguities removed in step (e) do not result in an unambiguous region sufficiently large to define the above set of unambiguous ranges, using time-of-arrival range information from each antenna device to each signal reflector and/or a priori information in conjunction with the less-ambiguous range from each antenna device to each signal reflector to obtain the unambiguous range from each antenna device to each signal reflector; (g) computing, using the unambiguous ranges and the three-dimensional coordinates of the antenna devices, the three-dimensional coordinates of each of the signal reflectors and thereby the boundary points; and (h) generating a mathematical-boundary-model using the boundary points obtained in step (g), for each combination of three antenna devices.
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8. A system for precisely measuring the positions of a generally symmetrical object in motion, in a predefined three-dimensional region, comprising in combination:
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(a) first, second, and third spaced antenna devices; (b) means for transmitting multiple radar signals from each of first, second, and third spaced antenna devices, respectively, into the three-dimensional region, the object reflecting multiple return signals corresponding to the multiple radar signals, respectively; (c) means for sensing the return signals by means of receivers connected to the first, second, and third antenna devices, respectively; (d) means for comparing the return signals with the corresponding transmitted multiple radar signals, respectively, to determine phases of the return signals relative to phases of the corresponding transmitted multiple radar signals, respectively, to obtain ambiguous representations of first, second, and third ranges of the object relative to the first, second, and third antenna devices, respectively; (e) means for removing ambiguities of the first, second, and third ranges using modular arithmetic to obtain first, second, and third less-ambiguous ranges or unambiguous ranges of the object relative to the first, second, and third antenna devices, respectively; (f) means for computing first, second, and third unambiguous ranges of the object, using first, second, and third time-of-arrival range information and/or a priori information in conjunction with the first, second, and third less ambiguous ranges if the ambiguities removed in step (e) do not result in an unambiguous region sufficiently large to define first, second, and third unambiguous ranges of the object; and (g) means for computing three-dimensional coordinates of the object using the first, second, and third unambiguous ranges and the coordinates of the first, second, and third antenna devices. - View Dependent Claims (9, 10, 11, 12)
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13. A system for precisely measuring the three-dimensional positions of a set of at least four spaced antenna devices and a set of spaced signal reflectors at various fixed positions relative to a three-dimensional region of interest, comprising in combination:
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(a) a set of at least four antenna devices and a set of signal reflectors; (b) means for taking a position of one of the antenna devices or signal reflectors as the origin of the three-dimensional coordinate system and taking a line between this origin and one other antenna device or corner reflector as one of the coordinate axes; (c) means for transmitting multiple radar signals from each of the set of spaced antenna devices, respectively, into the three-dimensional region containing the set of signal reflectors, means for each signal reflector reflecting multiple return signals corresponding to the multiple radar signals, respectively; (d) means for sensing the return signals of each signal reflector by means of receivers connected to each of the set of antenna devices, respectively; (e) means for comparing the return signals from each of the signal reflectors with the corresponding transmitted multiple radar signals, respectively, to determine phases of the return signals relative to phases of the corresponding transmitted multiple radar signals, respectively, to obtain ambiguous representations of the range of each antenna device relative to each signal reflector; (f) means for removing ambiguities of each of the set of ranges using modular arithmetic to obtain a less-ambiguous range or unambiguous range from each of the set of antenna devices to each of the set of signal reflectors; (g) means for using time-of-arrival range information from each antenna device to each signal reflector and/or a priori information in conjunction with the less-ambiguous range from each antenna device to each signal reflector to obtain the unambiguous range from each antenna device to each signal reflector, if the ambiguities removed by the means of step (f) do not result in an unambiguous region sufficiently large to define the above set of unambiguous ranges; (h) means for obtaining the crude three dimensional coordinates of each of the antenna devices and all signal reflectors from a priori information, and means for computing, using the unambiguous ranges and the crude three-dimensional coordinates, more precise three-dimensional coordinates of each antenna device and each signal reflector.
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14. A system for obtaining a mathematical-boundary-model of the region of interest, comprising in combination:
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(a) a set of at least three antenna devices and at least one signal reflector; (b) means for placing signal reflectors, either simultaneously or in sequence, on various boundary points of the three-dimensional region; (c) means for transmitting multiple radar signals from each of a set of at least three spaced antenna devices, respectively, into the three-dimensional region containing the signal reflectors, means for each signal reflector reflecting multiple return signals corresponding to the multiple radar signals, respectively; (d) means for sensing the return signals of each signal reflector by means of receivers connected to each of the set of antenna devices, respectively; (e) means for comparing the return signals from each of the signal reflectors with the corresponding transmitted multiple radar signals, respectively, to determine phases of the return signals relative to phases of the corresponding transmitted multiple radar signals, respectively, to obtain ambiguous representations of the range of each antenna device relative to each signal reflector; (f) means for removing ambiguities of each of the set of ranges using modular arithmetic to obtain a less-ambiguous range or unambiguous range from each of the set of antenna devices to each of the set of signal reflectors; (g) means for using time-of-arrival range information from each antenna device to each signal reflector and/or a priori information in conjunction with the less-ambiguous range from each antenna device to each signal reflector to obtain the unambiguous range from each antenna device to each signal reflector, if the ambiguities removed by means of step (f) do not result in an unambiguous region sufficiently large to define the above set of unambiguous ranges; (h) means for computing, using the unambiguous ranges and the three-dimensional coordinates of the antenna devices, the three-dimensional coordinates of each of the signal reflectors and thereby the boundary points for each combination of three antenna devices; and (i) means for generating a mathematical-boundary-model using the boundary points.
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Specification
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Current AssigneeGEC Marconi Limited (Gooding Consumer Electronics Ltd.)
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Original AssigneeMatrix Engineering Limited
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InventorsNuttall, Jerry A.
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Primary Examiner(s)Barron, Jr., Gilberto
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Application NumberUS07/747,380Time in Patent Office357 DaysField of Search342/59, 342/126, 342/463, 342/465, 342/127, 342/129, 273/29 RUS Class Current342/126CPC Class CodesA63B 2071/0611 Automatic tennis linesmen, ...A63B 2102/00 Application of clubs, bats,...A63B 2225/54 Transponders, e.g. RFIDA63B 43/00 Balls with special arrangem...A63B 71/0605 Decision makers and devices...G01S 13/46 Indirect determination of p...G01S 13/87 Combinations of radar syste...G01S 2013/466 by Trilateration, i.e. two ...
