JP2006061330A - Athletic measuring system and time measuring method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an athletic measuring system capable of appropriately measuring an individual time of each athlete. <P>SOLUTION: When a timekeeping line L is deviated from the center of a timekeeping zone A as shown in Fig. (a), the time keeping line L is deviated from the intermediate value between a trigger IN and a trigger OUT detected by a wireless tag as shown in Fig. (b). That is to say, the positional relationship between the trigger IN/trigger OUT and the timekeeping line L is a relationship shown in Fig.(c). The γ shown in Fig. (c) becomes a parameter obtained by digitizing the positional relationship between the timekeeping zone Z (the trigger IN and the trigger OUT) and the timekeeping line L. A tag console calculates the timekeeping time of a time point when the athlete passes the timekeeping time from the respective detection times in the both ends of the timekeeping zone Z obtained from the wireless tag based on the parameter (γ). <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a competition measurement system and a time measurement method capable of appropriately measuring the time of each individual athlete.

In recent years, attempts have been made to measure individual athletes' times in marathon competitions and the like. For example, a measurement system that measures a competitor's individual time based on the time when a barcode is printed on the athlete's race bib and the reader reads the barcode of the athlete who finished the goal has been put into practical use. .
Nevertheless, since this measurement system reads the barcode over a predetermined time after the goal, the time delayed from the actual measurement was measured in the first place. In particular, when a large number of athletes have scored at the same time, there is a problem that waiting for bar code reading occurs and a time considerably delayed from the actual measurement is measured.
In addition to the goal time, there is an increasing demand to measure the passing time at each timekeeping point (intermediate point, etc.), but this measurement system could not cope.

In order to solve such problems, various measurement systems have been developed, and operation tests and the like for practical use have been attempted. In order to measure time closer to actual measurement and to enable measurement at each timing point, the new measurement system is mainly used to measure the time of each individual player without contact. .
Specifically, the time is measured by a radio signal emitted from a transmitter (attached to the bib) carried by the athlete, or the competitor or bib etc. is identified from the photographed video. It is to measure.

Among other things, various devices have been devised for the practical use of measuring systems that allow athletes to carry transmitters. As an example, there is also a technology in which a trigger signal is transmitted by a transmitter within a narrow range along the goal line, and a unique number signal is automatically transmitted from the transmitter when the transmitter reaches the goal line together with the competitor. It is disclosed (for example, see Patent Document 1).
JP-A-8-57104 (Page 3-6, Fig. 1)

  The technique disclosed in Patent Document 1 measures the time (time) from the start when the receiver receives the unique number signal transmitted from the transmitter. When a large number of athletes reach the goal line at the same time, the unique number signals transmitted from the transmitters may overlap each other and cannot be identified. For this reason, the transmitter does not transmit the unique number signal only once, but transmits the unique number signal a plurality of times, thereby preventing the receiver from reading (missing) the unique number.

However, since the time to be measured is counted when the unique number signal can be received, if the unique number signal overlaps, the receiver misses the unique number signal and receives the next unique number, There was a problem that the measured time was somewhat delayed from the actual measurement.
In addition, since the measurement of the time due to the reception of the unique number signal must be performed within a limited range (within a narrow range in which the trigger signal is transmitted), there are many overlapping of the unique number signals. There is a problem that even if a plurality of transmissions are made, the unique number signal may be missed.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a competition measurement system and a time measurement method capable of appropriately measuring the time of each player.

In order to achieve the above object, a measurement system for competition according to the first aspect of the present invention is:
Timing device carried by the athlete, a signal generating device that emits a trigger signal into a predetermined timing zone including a timing line that defines the timing position, and time reception that receives a detection time sent from the timing device A competition measuring system including a machine and a console for controlling the time receiver,
The timing device is
A time measuring means for measuring a time synchronized with a reference time used as a reference for time measurement;
Detecting means for detecting the trigger signal emitted by the signal generating device;
Identifying means for determining the time zone based on the trigger signal detected by the detection means, and specifying the time measured by the time measuring means at two points of the determined time zone as the detection time;
Transmitting means for transmitting each of the detection times specified by the specifying means to the time receiver,
The console is
Storage means for storing a parameter defining a positional relationship between the time zone and the time line measured in advance;
Time acquisition means for acquiring each detection time received by the time receiver;
Based on the parameters stored in the storage means, from the respective detection times acquired by the time acquisition means, a time calculation means for calculating a time measured at the time when the athlete has passed the time measurement line,
It is characterized by that.

According to this invention, in the time measuring device, the time measuring means measures the time synchronized with the reference time (for example, the running time, the current time, etc.) serving as the reference for time measurement. The detecting means detects a trigger signal generated by the signal generating device. The specifying means determines the time zone based on the trigger signal detected by the detection means, and specifies the times measured by the time measuring means at two points in the determined time zone as detection times. Then, the transmission means transmits each detection time specified by the specifying means to the time receiver. On the other hand, in the console, the storage means stores parameters that define the positional relationship between the time zone measured in advance and the time line. The time acquisition means acquires each detection time received by the time receiver. Then, the time calculation means calculates a time measurement time at the time when the athlete passes the time measurement line from each detection time acquired by the time acquisition means based on the parameters stored in the storage means.
In this way, the time measuring device specifies detection times at two points in the time measuring zone as the athlete runs, and transmits each detection time to the time receiver. On the other hand, the console stores parameters that define the positional relationship between the time zone and the time line measured in advance, and when each detection time is acquired via the time receiver, each detection is based on the stored parameters. From the time, the time when the competitor passes the time line is calculated.
As a result, the time of each competitor can be measured appropriately.

The detection means detects the trigger signal emitted by the signal generating device to detect one end of the player entering the time zone and one end of the player leaving the time zone,
The specifying unit may specify the time measured by the time measuring unit at both ends of the time zone detected by the detecting unit as the detection time.

The detection means detects the trigger signal emitted by the signal generating device via an antenna having a predetermined characteristic,
The storage means may store a parameter that defines a positional relationship between the detection position of the time zone and the time line measured in advance according to the antenna characteristics of the time measuring device.

The detection means detects the trigger signal via an antenna having a predetermined characteristic,
The storage means stores characteristic information that prescribes that the antenna of the timing device has forward or backward directivity with reference to a running athlete,
The time calculation means may calculate one of the detection times acquired by the time acquisition means as a time measurement time based on the characteristic information stored in the storage means.

The storage means stores installation information that defines that one end of the time zone is in contact with the time line as the parameter,
The time calculation means may calculate one of the detection times as the time measurement time based on the installation information stored in the storage means.

In order to achieve the above object, a time measuring method according to the second aspect of the present invention is:
Timing device carried by the athlete, a signal generating device that emits a trigger signal into a predetermined timing zone including a timing line that defines a timing position, and time reception that receives a detection time sent from the timing device And a time measurement method in a system including a console for controlling the time receiver,
In the time measuring device, a time measuring step for measuring a time synchronized with a reference time used as a time reference,
In the timing device, a detection step of detecting a trigger signal emitted by the signal generation device;
A determination step of determining a time zone based on the trigger signal detected in the detection step, and specifying a time measured in the time measurement step at two points of the determined time zone as a detection time,
A transmission step of transmitting each detection time identified in the identification step toward a time receiver;
A time acquisition step of acquiring each detection time received by the time receiver at the console;
Based on the parameters defining the positional relationship between the time zone and the time line measured in advance, which is stored in a predetermined storage unit included in the console, the athlete measures the time line from each detection time acquired by the time acquisition step. A time calculation step for calculating the time measured when passing through
It is characterized by providing.

According to the present invention, the time measuring step measures a time synchronized with a reference time (for example, a running time, a current time, etc.) serving as a time reference in the time measuring device. The detecting step detects a trigger signal generated by the signal generating device in the timing device. In the specifying step, the time zone is determined based on the trigger signal detected in the detection step, and the times measured in the time measuring step at two points in the determined time zone are specified as detection times. In the transmission step, each detection time identified in the identification step is transmitted to the time receiver. The time acquisition step acquires each detection time received by the time receiver in the console. Then, the time calculation step includes each detection time acquired by the time acquisition step based on a parameter that is stored in a predetermined storage unit of the console and that defines a positional relationship between the time zone and the time line measured in advance. From the above, the time measured when the competitor passes the time line is calculated.
As described above, in the time measuring device, the detection time is specified at two points in the time measuring zone as the athlete runs, and each detection time is transmitted to the time receiver. On the other hand, in the console, parameters that define the positional relationship between the time zone and the time line measured in advance are stored, and when each detection time is acquired via the time receiver, each detection is performed based on the stored parameters. From the time, the time when the competitor passes the time line is calculated.
As a result, the time of each competitor can be measured appropriately.

  According to the present invention, it is possible to appropriately measure the time of each individual player.

  A competition measurement system according to an embodiment of the present invention will be described below with reference to the drawings. In addition, as an example, it demonstrates as a measurement system for competitions which measures time etc. at a plurality of points in a marathon competition.

(Embodiment 1)
FIG. 1 is a schematic diagram showing an example of the configuration of a competition measurement system 1 applied to the embodiment of the present invention. In the following description, the relay points and goal points at which time is measured will be collectively described as time points for convenience. That is, the time point indicates a relay point or a goal point. A case where the goal point is different from the start point will be described.

  As shown in the figure, the competition measurement system 1 includes a timer console 11, a GPS receiver 12, a wireless communication terminal 13, a time display device 14, a running time transmitter 15, a tag ID receiver 16 installed at the start point, and , A tag console 17, a timer console 11 installed at a timing point (relay point or goal point), a GPS receiver 12, a wireless communication terminal 13, a time display device 14, a running time transmitter 15, a tag ID receiver 16, A trigger signal generator 18 as a signal generator machine, a detection time receiver 19 as a time receiver, a tag console 20 as a console, a photographing device 21, a video recording device 22, a data server 23, and each player RN And a wireless tag 30 as a timekeeping device to be carried.

A start pistol SP is connected to the timer console 11 at the start point, and a grip switch GS is connected to the timer console 11 at the time point.
In response to the starter operation, the start pistol SP supplies a start signal to the timer console 11 at the start point. Further, the grip switch GS supplies a grip signal to the timer console 11 at the timing point in response to an operation of a time officer or the like.

The timer console 11 is a control unit such as a CPU (Central Processing Unit), a memory such as a RAM (Random Access Memory), a display unit such as an LCD (Liquid Crystal Display), a timer for measuring a running time, and an operation of a keyboard, etc. Part.
The timer console 11 executes time synchronization processing before the start of the competition, and starts measuring the current time synchronized with the standard time received by the GPS receiver 12.

When the start signal is input from the start pistol SP at the start of the competition, the timer console 11 at the start point holds the time as its start time (time information) in its own memory and the wireless communication terminal 13 is controlled to transmit the start time to the timer console 11 at the time point.
On the other hand, when the timer console 11 at the time point receives the start time sent from the wireless communication terminal 13 at the start point, the timer console 11 acquires the start time from the wireless communication terminal 13 and holds it in its own memory. To do.
After holding the start time in its own memory in this way, the timer console 11 sequentially generates a running time based on the difference between the current time measured by its own timer and the held start time. The information is supplied to the time display device 14 as information.
Further, when a grip signal is input from the grip switch GS, the timer console 11 at the timing point supplies the time to the video recording device 22 or the like as the grip time (time information).

  A GPS (Global Positioning System) receiver 12 receives a standard time (GPS time) transmitted from a GPS satellite, and supplies the received standard time to the timer console 11.

The wireless communication terminal 13 is a mobile phone or the like capable of data communication with another wireless communication terminal 13 through a public line (such as a mobile communication network).
Then, the wireless communication terminal 13 at the start point transmits communication data including the start time supplied from the timer console 11 to the wireless communication terminal 13 at the time point.
On the other hand, the wireless communication terminal 13 at the timing point receives the start time sent from the wireless communication terminal 13 at the start point, and supplies the received start time to the timer console 11.

  The time display device 14 includes an electric bulletin board or the like, and displays a running time or the like according to time information sequentially supplied from the timer console 11.

The running time transmitter 15 transmits the running time measured by the timer console 11 to each competitor RN (each wireless tag 30) and appropriately corrects (or sets) the time counted by the wireless tag 30. )
Specifically, the running time transmitter 15 at the start point transmits information including the running time, the gateway ID, and the threshold value n to all the wireless tags 30 immediately after the start by broadcasting. This gateway ID is identification information unique to the running time transmitter 15 (starting point or timing point), and the threshold value n is determined by the wireless tag 30 to determine the accuracy of the transmitted running time. Is the value used to
The running time transmitter 15 at the start point transmits the running time and the like continuously over a plurality of times (for example, three times or more at intervals of one second) in order to cause the wireless tag 30 to set the time first.
On the other hand, the running time transmitter 15 at the time point is arranged in front of the measurement point (time line L described later) as viewed from the traveling player RN, and toward the wireless tag 30 of the player RN located in the vicinity. , Information including running time and gateway ID is transmitted.
Note that the running time transmitter 15 at the start point transmits test data such as the current time to each wireless tag 30 for operation confirmation before starting.

The tag ID receiver 16 receives a tag ID returned from the wireless tag 30 in response to the running time transmitted by the running time transmitter 15 (identification information unique to the wireless tag 30). Then, the received tag ID is supplied to the tag console 17.
As with the running time transmitter 15, the tag ID receiver 16 at the time point is also arranged in front of the measurement point as viewed from the running player RN, and the player RN reaches the time zone Z described later. Before, the tag ID returned from the wireless tag 30 is received.
Further, the tag ID receiver 16 at the start point also receives a tag ID returned from the wireless tag 30 in response to test data (current time, etc.) for operation confirmation before starting.

The tag console 17 includes a control unit such as a CPU, a memory such as a RAM, a display unit such as an LCD, and an operation unit such as a keyboard, and manages a tag ID transmitted from the wireless tag 30.
Specifically, the tag console 17 confirms the competition start of each player RN from each tag ID acquired after the start. In addition, when the tag ID for the test data is not acquired before the start, the wireless tag 30 that should transmit the tag ID may be out of order or the battery may run out.

The trigger signal generation device 18 is installed, for example, from a roadside to a timing line L (a determination line that defines a timing position), and generates a trigger signal in a timing zone Z within a predetermined range including the timing line L. .
As an example, the trigger signal generation device 18 generates a microwave of 24 GHz, and transmits a trigger signal toward the time zone Z by a predetermined parabolic antenna as shown in FIG.
In addition to this, the trigger signal generator 18 may generate a long-wave band trigger signal in the time zone Z using a loop coil (loop antenna) as shown in FIG.

  When the player RN enters the time zone Z, the wireless tag 30 detects a trigger signal. Although details will be described later, the wireless tag 30 detects a trigger signal when entering the time zone Z (trigger IN), and specifies a detection time measured at that time. When the player RN runs (moves) and leaves the time zone Z, the wireless tag 30 finishes detecting the trigger signal (trigger OUT), and specifies the detection time measured at that time. That is, the wireless tag 30 specifies the detection times at both ends (two points) of the time zone Z.

The detection time receiver 19 is controlled by the tag console 20 and receives detection time and the like by polling from the wireless tag 30 of the player RN (after passing through the time zone Z) located in the vicinity.
Specifically, the detection time receiver 19 requests each wireless tag 30 to transmit the detection time in accordance with the order of a polling list described later of the tag console 20 and detects the detection time transmitted from the wireless tag 30 in response (described later). As described above, the tag ID, the detection time at two points, the barrier ID, and the correction value α) are received.
When a polling request is transmitted from the wireless tag 30 side as will be described later, the detection time receiver 19 requests the wireless tag 30 to transmit the detection time and receives the detection time and the like.

The tag console 20 controls the detection time receiver 19 and acquires the detection time transmitted from the wireless tag 30.
Specifically, as shown in FIG. 3, the tag console 18 includes a tag ID acquisition unit 20a, a list storage unit 20b, a detection time acquisition unit 20c as a time acquisition unit, a storage unit 20d as a storage unit, and a time It includes a control unit 20e as a calculation means, a display unit 20f, an operation unit 20g, and a communication unit 20h.

The tag ID acquisition unit 20 a acquires the tag ID from the tag ID receiver 16 when the tag ID receiver 16 receives the tag ID sent from the wireless tag 30.
The list storage unit 20b stores a polling list as shown in FIG. This polling list is appropriately generated by the control unit 20e.

The detection time acquisition unit 20 c acquires the detection times and the like from the detection time receiver 19 when the detection time receiver 19 receives the detection times and the like at two points sent from the wireless tag 30. Specifically, information including the tag ID received by the detection time receiver 19, the detection time at two points, the barrier ID, and the correction value α is acquired.
The correction value α is a value obtained from the accumulated time difference β obtained by accumulating the corrected time (time difference) every time the wireless tag 30 receives the running time.

The storage unit 20d stores parameters obtained by quantifying the positional relationship between the time zone Z and the time line L.
This parameter is used to obtain the time (timed time) at which the player RN passed the timed line L from the detection time at two points.
In general, when the trigger signal generator 18 is arranged, as shown in FIG. 5A, the time zone Z is formed so that the time line L is located at the center. In this case, as shown in FIG. 5 (b), an intermediate value between the detection time of the trigger IN and the detection time of the trigger OUT becomes the time measurement time (exception at the goal point will be described later).
However, in practice, the trigger signal generator 18 may not be arranged so that the timing line L is located in the center of the timing zone Z.
For example, when the time line L has shifted from the center of the time zone Z as shown in FIG. 6A due to the conditions of the installation location (temperature, humidity, material, etc.), FIG. As shown, the time measurement line L deviates from the intermediate value between the trigger IN and the trigger OUT detected by the wireless tag 30. That is, the positional relationship between the trigger IN, the trigger OUT, and the timing line L is the relationship shown in FIG.

Even if the trigger signal generator 18 can be arranged so that the timing line L is located in the center of the timing zone Z, the timing zone is substantially reduced depending on the characteristics of the antenna of the wireless tag 30 (a trigger antenna 35 described later). In some cases, the time measurement line L may deviate from the center of Z.
For example, as shown in FIG. 7 (a), even if the timing line L is located in the center of the timing zone Z, as shown in FIG. 7 (b) due to the antenna characteristics (directivity, etc.) of the wireless tag 30. In addition, the time measurement line L deviates from an intermediate value between the trigger IN and the trigger OUT that can be detected by the wireless tag 30 substantially. That is, the positional relationship between the trigger IN, the trigger OUT, and the timing line L is the relationship shown in FIG.

  Such γ shown in FIGS. 6C and 7C is a parameter obtained by quantifying the positional relationship between the time zone Z (trigger IN, trigger OUT) and the time line L. Such a parameter (γ) is obtained in advance by a competition official or the like using a predetermined measuring device or the like after the trigger signal generator 18 is actually installed. Then, the obtained parameter (γ) is stored in the storage unit 20d before the start of the competition.

The control unit 20e appropriately generates a polling list as shown in FIG. 4 in the list storage unit 20b and controls the detection time receiver 19 to receive the detection time and the like from the wireless tag 30.
Specifically, when the tag ID is acquired by the tag ID acquisition unit 20a, the control unit 20e registers the tag ID in the polling list. If the tag ID cannot be acquired (the tag ID receiver 16 cannot receive the tag ID), the control unit 20e registers the target tag ID in the polling list according to the input from the operation unit 20g. To do.
In accordance with the polling list generated in this way, the control unit 20e controls the detection time receiver 19, and acquires information including the tag ID sent from the wireless tag 30, each detection time, the gateway ID, and the correction value α. To do.
When the gateway ID is different from the gateway ID of the running time transmitter 15 at the timing point (when it is the gateway ID of the running time transmitter 15 at the timing point or the start point that has passed before), the control unit 20e. Uses the correction value α acquired together with each detection time to appropriately correct each detection time.

And the control part 20e calculates the time measuring time at the time of the player RN passing the time measuring line L from each detection time based on the parameter memorize | stored in the memory | storage part 20d.
Specifically, the control unit 20e assigns the parameter (γ) stored in the storage unit 20d and the detection time at two points to either of the following formulas 1 and 2, so that the player RN counts the time line L The time measured when passing through is obtained.

(Equation 1)
T = Tin + (Tot−Tin) × γ
T: Timekeeping time Tin: Trigger IN detection time Tot: Trigger OUT detection time γ: Parameter

(Equation 2)
T = Tot− (Tot−Tin) × γ
T: Timekeeping time Tin: Trigger IN detection time Tot: Trigger OUT detection time γ: Parameter

Thereby, even when the trigger signal generator 18 cannot be arranged so that the timing line L is located in the center of the timing zone Z or when the antenna of the wireless tag 30 has characteristics (directivity, etc.) Can be requested.
And the control part 20e will transmit to the data server 23 with tag ID via the communication part 20h, if time-measurement time is calculated. After transmitting the measured time and the like to the data server 23, the control unit 20e deletes the corresponding tag ID from the polling list. In addition, when there is a tag ID that remains without being deleted from the polling list after a certain period of time, the control unit 20e generates non-passer-by information including the tag ID, and via the communication unit 20h, Transmit to the video recording device 22.

The display unit 20 f displays information indicating the operation status of the tag console 20. For example, a polling list or the like stored in the list storage unit 20b is displayed.
The operation unit 20g supplies instruction information or the like according to the operation of the competition officer or the like to the control unit 20e or the like. For example, when a tag ID or the like to be added to the polling list is input, the tag ID is supplied to the control unit 20e or the like.

  The communication unit 20h transmits the time measured calculated by the control unit 20e to the data server 23 together with the tag ID.

The imaging device 21 is composed of, for example, a video camera or the like, and captures an image of the player RN passing through the timing line L.
Specifically, the imaging device 20 is arranged farther than the trigger signal generator 18 as viewed from the running player RN, and the front (front) of the player RN can be seen so that the bib number, face, etc. of the player RN can be understood. Take a picture. Then, the captured video (video signal) is supplied to the video recording device 22.

The video recording device 22 is composed of a video recording device or the like, and synthesizes (synchronizes) time data such as grip time and running time supplied from the timer console 11 with video (video signal) supplied from the imaging device 21. Record).
Then, when the non-passer information is transmitted from the tag console 20, the recorded video is appropriately searched and the time of the non-passer is specified.

The data server 23 appropriately acquires data from the tag console 20 and determines the official time, arrival order, and the like.
Prior to the start of the competition, when the player information of the player RN, the tag ID of the wireless tag 30 to be used, and the like are input from a predetermined operation unit, the data server 23 stores these information in association with each other. Then, the data is supplied to the timer console 11, the tag console 20, and the video recording device 22 as appropriate.

The wireless tag 30 as a timing device carried by the player RN receives the running time transmitted from the starting time or the running time transmitter 15 at the timing point, and measures the time synchronized with the running time. Then, the trigger signal generated from the trigger signal generator 18 at the timing point is detected, the detection times at the two points in the timing zone Z are specified, and the detection time is transmitted to the detection time receiver 19 in response to polling.
Specifically, as shown in FIG. 8, the wireless tag 30 includes an antenna 31, a receiving unit 32, a time correction unit 33, a time measuring unit 34 as a time measuring means, a trigger antenna 35, and trigger detection as a detecting means. The unit 36 includes a time specifying unit 37 as specifying means, a storage unit 38, and a transmitting unit 39 as transmitting means.

The antenna 31 is a transmission / reception antenna.
The receiving unit 32 receives the running time transmitted from the running time transmitter 15 through the antenna 31.
Specifically, the receiving unit 32 receives information including the running time, the barrier ID, and the threshold value n transmitted from the running time transmitter 15 at the start point immediately after the start. At this time, the running time transmitter 15 continuously receives a running time transmitted over a plurality of times (for example, three times or more at intervals of 1 second).
The receiving unit 32 receives information including the running time and the gateway ID transmitted from the running time transmitter 15 at the time point.
Then, the receiving unit 32 supplies the received running time and the like to the time correction unit 33.
In addition, the receiving unit 32 receives a detection time transmission request (polling) from the detection time receiver 19. Then, the received transmission request is supplied to the transmission unit 39.

The time correction unit 33 corrects the running time counted by the timing unit 34 based on the running time received by the receiving unit 32 at the timing point. At that time, the time difference (time difference between the received running time and the running time measured by the time measuring unit 34) is obtained and added to the accumulated time difference β of the storage unit 38 and stored. Then, a correction value α per unit time is obtained from the accumulated time difference β and stored (updated) in the storage unit 38. In addition, in order to clarify the timing point where the time correction is performed, the gateway ID sent together with the running time is stored (updated) in the storage unit 38.
Since the running time has not been set in the timing unit 34 until the start of the competition, the time correction unit 33 indicates the running time sent from the running time transmitter 15 at the start point. After receiving three or more times at 1-second intervals, a valid running time is set in the timing unit 34.
At this time, the time correction unit 33 stores the threshold value n sent together with the running time from the running time transmitter 15 at the start point in the storage unit 38.

  When the time difference between the received running time and the running time measured by the timing unit 34 is larger than the threshold value n stored in the storage unit 38 at the timing point, the time correction unit 33 performs time correction. Not performed. This is because, for some reason, the transmitted running time or the received running time may be garbled, etc., so the time correction unit 33 discards the inaccurate running time as it is. To do. In this case, the gateway ID is not updated.

The time measurement unit 34 is appropriately corrected (set) by the time correction unit 33 and measures the running time synchronized with the running time received by the receiving unit 82.
The timekeeping unit 34 includes a highly stable crystal oscillator, and can stably keep the running time.

The trigger antenna 35 is tuned to a microwave or electromagnetic wave emitted from the trigger signal generator 18 and receives a trigger signal.
The trigger detection unit 36 detects a trigger signal via the trigger antenna 35. Then, the detection result is notified to the time specifying unit 37. For example, the trigger detection unit 36 detects the trigger IN timing (the timing when the trigger signal is first detected from the state where the trigger signal is not detected) and the trigger OUT timing (when the trigger signal is detected). The time specifying unit 37 is notified of the (finished timing).

The time specifying unit 37 determines the time zone Z based on the trigger signal detected by the trigger detection unit 36, and specifies the running time measured by the time unit 34 at both ends of the time zone Z as the detection time.
For example, when the athlete RN reaches the time zone Z and the timing of the trigger IN is notified from the trigger detection unit 36, the time specifying unit 37 detects the first running time that the time measurement unit 34 measures. The time is specified and stored in the storage unit 38. Thereafter, when the athlete RN passes the time zone Z and the trigger detection unit 36 is notified of the timing of the trigger OUT, the running time measured by the time measurement unit 34 is specified as the second detection time and stored. Store in the unit 38.

The storage unit 38 stores the threshold value n received by the receiving unit 32, the correction value α obtained by the time correction unit 33, the accumulated time difference β, the gateway ID of the point where the time correction is performed, and the time specifying unit 37. Each detected time is stored.
Moreover, the memory | storage part 38 has memorize | stored beforehand unique tag ID different for every radio | wireless tag 30 (every player RN).

When the reception unit 32 receives the running time, the transmission unit 39 transmits the tag ID read from the storage unit 38 to the tag ID receiver 16 as a response. At that time, in order to suppress the occurrence of collision, the tag ID is transmitted at a different response timing determined for each wireless tag 30. In addition, it is possible to use a plurality of wireless channels and to allocate the wireless tags 30 to different channels, thereby suppressing the occurrence of collision.
Further, when the receiving unit 32 receives the detection time transmission request (polling), the transmission unit 39 reads the tag ID, each detection time, the gateway ID, and the correction value α from the storage unit 38 to detect the detection time. Transmit to the receiver 19.
The transmission unit 39 may itself transmit a polling request to the detection time receiver 19 when a detection time transmission request (polling) is not transmitted from the detection time receiver 19. For example, in consideration of the fact that its own tag ID is not registered in the polling list of the tag console 20, detection is performed by the time specifying unit 37 after the detection time is stored in the storage unit 38 and after a predetermined time has elapsed. If the time transmission request is not received, the transmission unit 39 voluntarily transmits a polling request to the detection time receiver 19. At this time, the transmission unit 39 may shift the timing in consideration of the transmission of the other wireless tag 30, or may transmit a polling request in a band of a different channel.

Hereinafter, operation | movement of the measurement system 1 for competitions of the structure mentioned above is demonstrated with reference to drawings.
First, the operation from the start of the competition until the tag console 20 generates the polling list will be briefly described with reference to FIG.

  First, immediately after the start, as shown in FIG. 9A, the running time transmitter 15 at the start point is continuously directed to the wireless tag 30 a plurality of times (for example, three times or more at 1 second intervals). The running time is transmitted across (T1).

The wireless tag 30 identifies a valid running time from a plurality of running times, and sets the identified running time in the time measuring unit 34 (T2). The wireless tag 30 stores the gateway ID and the threshold value n sent together with the running time in the storage unit 38.
Then, the wireless tag 30 transmits its own tag ID to the tag ID receiver 16 as a response to the received running time (T3).

  The tag console 17 at the start point confirms the start of the player RN based on the tag ID received by the tag ID receiver 16.

  Thereafter, when the athlete RN travels to the time point (before the time zone Z), as shown in FIG. 9B, the running time transmitter 15 at the time point transmits the running time and the like to the wireless tag 30 ( T4).

The wireless tag 30 corrects the time of the time measuring unit 34 after determining the validity of the received running time (T5).
Specifically, when the wireless tag receives the running time, the wireless tag obtains a time difference from the running time that the wireless tag measures. Then, the calculated time difference is compared with the threshold value n to determine whether or not the running time is accurate.
Here, the wireless tag 30 corrects its running time when the obtained time difference is not larger than the threshold value n (within the threshold value n). Then, the obtained time difference is added to the accumulated time difference β of the storage unit 38 and stored, and the correction value α per unit time is obtained from the accumulated time difference β and stored (updated) in the storage unit 38. The gateway ID is also updated.
On the other hand, when the calculated time difference is larger than the threshold value n, the wireless tag 30 discards the running time that seems to be inaccurate and does not update the gateway ID.
Then, the wireless tag 30 transmits its own tag ID to the tag ID receiver 16 as a response to the received running time (T6).

When receiving the tag ID sent from the wireless tag 30, the tag console 20 at the timing point registers this tag ID in the polling list (T7).
Note that the tag console 20 also registers this tag ID in the polling list when a manual tag ID is input from the operation unit. That is, when the tag console 20 cannot acquire the tag ID (the tag ID receiver 16 cannot receive the tag ID), the competition officer or the like operates the tag console 20 and cannot detect the tag. The ID (tag ID corresponding to the wireless tag 30 of the target player RN) is manually input.

  In this manner, a polling list is generated and registered in the tag console 20 before the competitor RN reaches the time zone Z.

  Next, with reference to FIG. 10, the operation for calculating the time measured by the tag console 20 that has generated the polling list will be described. FIG. 10 is a flowchart for explaining the time counting calculation process executed by the tag console 20.

First, the tag console 20 reads one tag ID from the polling list (step S11). That is, the tag console 17 reads the tag ID registered in the polling list in a predetermined order.
For example, the tag console 20 reads one tag ID according to the order of registration time. When this step S11 is repeatedly executed and the tag ID having the latest registration time is read, the tag console 20 again starts the tag from the top again in the order of the earlier registration time when the previous tag ID remains. Read the ID.

  The tag console 20 determines whether or not a certain time has elapsed since the tag ID was registered in the polling list (step S12). That is, it is determined whether or not the read tag ID is in a state in which polling reception cannot be performed and the tag ID remains without being deleted from the polling list even after a predetermined time has elapsed.

  When the tag console 20 determines that the predetermined time has not elapsed, the tag console 20 causes the detection time receiver 19 to receive the detection time by polling (step S13). That is, the tag console 20 controls the detection time receiver 19 to request transmission of the detection time to the wireless tag 30 with the tag ID read from the polling list, and in response, the tag ID sent from the wireless tag 30. Information including each detection time, barrier ID, and correction value α is acquired.

  The tag console 20 determines whether or not the gateway ID matches that at the time point (step S14). That is, the tag console 20 determines whether or not the received gateway ID is the same as the gateway ID of the running time transmitter 15 at the timing point. Here, when the gateway IDs match, the running time of the wireless tag 30 is corrected at the timing point. On the other hand, when the gateway IDs do not match, correction is performed at the timing point. Is not performed, and correction is performed at the previous timing point.

If the tag console 20 determines that the gateway IDs match, the tag console 20 does not need to correct each detection time, and thus proceeds to step S16 described later.
On the other hand, when it is determined that the barrier IDs do not match, the tag console 20 corrects each detection time using the correction value α (step S15).

The tag console 20 calculates a time measurement from each detection time based on a parameter obtained by digitizing the positional relationship between the time measurement zone Z and the time measurement line L (step S16).
That is, the tag console 20 calculates a time measurement time when the player RN passes the time measurement line L from each detection time based on the parameter (γ) stored in the storage unit 20d. More specifically, the time measurement is obtained using the above-described formulas 1 and 2 and the like.

  The tag console 20 transmits the calculated timing time to the data server 23 (step S17). That is, the tag console 20 transmits the time measured calculated using the parameter (γ) and each detection time to the data server 23 together with the tag ID.

  The tag console 20 deletes the target tag ID from the polling list (step S18). That is, the tag ID of the wireless tag 30 that has become unnecessary after the calculation of the time measurement is deleted from the polling list.

  On the other hand, if it is determined in step S12 that a certain time has elapsed, the tag console 20 generates non-passer-by information including the tag ID and supplies it to the video recording device 22 (step S19). ).

Then, the tag console 20 determines whether another tag ID is registered in the polling list (step S20).
If it is determined that there is another tag ID, the tag console 20 returns the process to step S11 and repeatedly executes the processes of steps S11 to S20 described above.
On the other hand, when it is determined that there is no other tag ID, the tag console 20 ends the time counting process.

As described above, when the time counting calculation process performed by the tag console 20 at the time point, the trigger signal generator 18 cannot be disposed so that the time line L is located at the center of the time zone Z, Even if there are characteristics (directivity, etc.), the timekeeping time of the competitor can be obtained.
As a result, the time of each competitor can be measured appropriately.

In the above embodiment, the tag console 20 (storage unit 20d) stores a parameter obtained by quantifying the positional relationship between the time zone Z and the time line L, and based on this parameter, the time count is calculated from each detection time. We explained the case of calculating
However, the information to be stored in the tag console 20 (storage unit 20d) is not limited to such parameters. In addition, the characteristic information that defines the characteristics of the trigger antenna 35 of the wireless tag 30 and the installation of the trigger signal generator 18 are also included. Installation information that defines the installation environment including points may be stored.

For example, when the trigger antenna 35 of the wireless tag 30 has directivity forward or backward with reference to the running player RN, the tag console 20 (storage unit 20d) defines the directivity. Remember information.
In addition, when the trigger antenna 35 has directivity forward with respect to the running player RN, the trigger signal from the front is easily received, but the trigger signal from the rear is difficult to receive. Conversely, when the trigger antenna 35 has directivity on the rear side, it is easy to receive the trigger signal from the rear, but it is difficult to receive the trigger signal from the front.
Considering such a case, the trigger signal generator 18 is arranged so that one end (end A) of the time zone Z is in contact with the time line L, as shown in FIGS. As shown in FIGS. 11C and 11D, the trigger signal generator 18 may be arranged so that the other end (end B) of the time zone Z is in contact with the time line L.
In such a case, the tag console 20 (control unit 20e) calculates one of the detection times acquired by the detection time acquisition unit 20c as a time measurement time based on the characteristic information stored in the storage unit 20d.
For example, when the trigger antenna 35 has directivity forward and the end B of the time zone Z is in contact with the time line L as shown in FIGS. Calculates the detection time of the trigger OUT as a time measurement time.

In addition to this, at the goal point, unlike the other measurement points, the speed of the player RN greatly differs before and after the timing line L. At a relay point other than the goal point, the player RN usually travels (passes) around the time line L at a substantially constant speed. However, at the goal point, when the player RN passes the goal line (the time line L), the speed is drastically reduced.
For this reason, it is difficult to accurately calculate the time measurement time from the detection times at the two points.
Also in this case, as shown in FIGS. 11A and 11B, the trigger signal generator 18 is disposed so that the end A of the time zone Z is in contact with the time line L, or FIG. , (D), it is necessary to arrange the trigger signal generator 18 so that the end B of the time zone Z is in contact with the time line L.
That is, when the installation point of the trigger signal generator 18 is the goal point, the tag console 20 (storage unit 20d) stores installation information that specifies that one end of the time zone is in contact with the time line. Let
And the tag console 20 (control part 20e) calculates one of each detection time which the detection time acquisition part 20c acquired based on the installation information memorize | stored in the memory | storage part 20d as time-measurement time.
Even in these cases, the time of each competitor can be measured appropriately.

In the above-described embodiment, the case where the running time is transmitted from the running time transmitter 15 toward the wireless tag 30 and the time synchronized with the running time is counted by the timing unit 34 of the wireless tag 30 has been described.
However, what is transmitted from the running time transmitter 15 is not limited to the running time, and other time information may be transmitted. For example, the current time measured by the timer console 11 is transmitted from the running time transmitter 15 to the wireless tag 30, and the wireless tag 30 (timer unit 34) measures the time synchronized with the current time. It may be.

More specifically, the running time transmitter 15 at the start point includes the current time, the gateway ID, and the threshold value n all at once by broadcast to all the wireless tags 30 before the competition starts. Send information. At this time, the running time transmitter 15 transmits the current time and the like continuously over a plurality of times (for example, three times or more at intervals of 1 second).
On the other hand, the wireless tag 30 sets a valid current time in the time measuring unit 34 in consideration of a plurality of current times that should change with time. Then, the threshold value n and the first set time sent together with the current time are stored in the storage unit 38.

When the competition starts and the competitor RN advances to the time point, the wireless tag 30 receives the current time sent from the running time transmitter 15 at the time point. When this current time is received, the wireless tag 30 (time correction unit 33) corrects the time counted by the time measurement unit 34 based on the received current time. At this time, the corrected time difference (the time difference between the received current time and the time measured by the time measuring unit 34) is obtained and added to the accumulated time difference β of the storage unit 38 and stored. Then, a correction value α per unit time is obtained from the accumulated time difference β and stored (updated) in the storage unit 38. In addition, in order to clarify the corrected timing point, the gateway ID sent together with the current time is stored (updated) in the storage unit 38.
Also in this case, when the time difference between the current time received at the timing point and the time measured by the timing unit 34 is larger than the threshold value n stored in the storage unit 38, the time correction unit 33 sets the time Do not make corrections.

Then, the wireless tag 30 stores each detection time specified at two points based on the detected trigger signal in the storage unit 38, and then responds to polling in response to polling, the tag ID, each detection time, the barrier ID, and the correction. The value α is read from the storage unit 38 and transmitted to the detection time receiver 19.
On the other hand, when the tag console 20 acquires these pieces of information via the detection time receiver 19, the correction acquired along with the detection time when the barrier ID is different from the gateway ID of the running time transmitter 15 at the timing point. Each detection time is corrected appropriately using the value α. Based on the parameter (γ), the tag console 20 calculates the time measured when the player RN passes the time line L from each detection time. The tag console 20 transmits the calculated time measurement time to the data server 23 together with the tag ID. Then, the data server 23 specifies the time of each player RN from the start time and the measured time.

  In the above embodiment, the case where the start point and the goal point are different has been described as an example. However, the present invention can be similarly applied to the case where the start point and the goal point are the same.

In the above embodiment, the marathon competition has been described as an example, but the competition to be timed is not limited to this and is arbitrary.
For example, the present invention can be applied as appropriate to relay races, racewalking, disabled wheelchair road races, bicycle road races, triathlons, and mountain sports such as running and orientation.

  As described above, according to the present invention, it is possible to appropriately measure the time of each player.

It is a schematic diagram which shows an example of a structure of the measurement system for competitions concerning embodiment of this invention. (A), (b) is a schematic diagram for demonstrating the time zone formed by a trigger signal generator. It is a block diagram which shows an example of a structure of the tag console arrange | positioned at a time measuring point. It is a schematic diagram which shows an example of a polling list. (A), (b) is a schematic diagram for demonstrating the time zone where a time measuring line is located in the center. (A)-(c) is a schematic diagram for demonstrating the time zone from which the time measurement line shifted | deviated from the center. (A)-(c) is a schematic diagram for demonstrating the time zone from which the time measuring line shifted | deviated from the center substantially by the characteristic of the antenna. It is a block diagram which shows an example of a structure of a wireless tag. (A) is a schematic diagram for demonstrating operation | movement of a wireless tag etc. at the time of a competition start, (b) is a schematic diagram for demonstrating operation | movement of a tag console etc. which produce | generate a polling list. It is a flowchart for demonstrating the time measurement calculation process which a tag console performs. (A)-(d) is a schematic diagram for demonstrating the case where a time measuring line touches one end of a time measuring zone.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Competition measuring system 11 Timer console 12 GPS receiver 13 Wireless communication terminal 14 Time display device 15 Running time transmitter 16 Tag ID receiver 17, 20 Tag console 18 Trigger signal generator 19 Detection time receiver 21 Shooting device 22 Video Recording device 23 Data server 30 Wireless tag

Claims (6)

Timing device carried by the athlete, a signal generating device that emits a trigger signal into a predetermined timing zone including a timing line that defines the timing position, and time reception that receives a detection time sent from the timing device A competition measuring system including a machine and a console for controlling the time receiver,
The timing device is
A time measuring means for measuring a time synchronized with a reference time used as a reference for time measurement;
Detecting means for detecting the trigger signal emitted by the signal generating device;
Identifying means for determining the time zone based on the trigger signal detected by the detection means, and specifying the time measured by the time measuring means at two points of the determined time zone as the detection time;
Transmitting means for transmitting each of the detection times specified by the specifying means to the time receiver,
The console is
Storage means for storing a parameter defining a positional relationship between the time zone and the time line measured in advance;
Time acquisition means for acquiring each detection time received by the time receiver;
Based on the parameters stored in the storage means, the time calculation means for calculating the time measured when the athlete passes the time measurement line from the respective detection times acquired by the time acquisition means,
Measuring system for competitions characterized by this. The detection means detects the trigger signal emitted by the signal generating device to detect one end of the player entering the time zone and one end of the player leaving the time zone,
The specifying means specifies the times measured by the timing means at both ends of the timing zone detected by the detection means as the detection times;
The competition measurement system according to claim 1, wherein: The detection means detects the trigger signal emitted by the signal generating device via an antenna having a predetermined characteristic,
The storage means stores a parameter that defines a positional relationship between the detection position of the time zone and the time line measured in advance according to the characteristics of the antenna of the time measuring device.
The competition measurement system according to claim 1, wherein the measurement system is for competition. The detection means detects the trigger signal emitted by the signal generating device via an antenna having a predetermined characteristic,
The storage means stores characteristic information that prescribes that the antenna of the timing device has forward or backward directivity with reference to a running athlete,
The time calculation means calculates one of the detection times acquired by the time acquisition means as a time measurement time based on the characteristic information stored in the storage means.
The competition measurement system according to claim 1, wherein the measurement system is for competition. The storage means stores installation information that defines that one end of the time zone is in contact with the time line as the parameter,
The time calculation means calculates one of the detection times acquired by the time acquisition means as the time measurement time based on the installation information stored in the storage means.
The competition measurement system according to claim 1, wherein the measurement system is for competition. Timing device carried by the athlete, a signal generating device that emits a trigger signal into a predetermined timing zone including a timing line that defines the timing position, and time reception that receives a detection time sent from the timing device And a time measurement method in a system including a console for controlling the time receiver,
In the time measuring device, a time measuring step for measuring a time synchronized with a reference time used as a time reference,
In the timing device, a detection step of detecting a trigger signal emitted by the signal generation device;
A determination step of determining a time zone based on the trigger signal detected in the detection step, and specifying a time measured in the time measurement step at two points of the determined time zone as a detection time,
A transmission step of transmitting each detection time identified in the identification step toward a time receiver;
A time acquisition step of acquiring each detection time received by the time receiver at the console;
Based on the parameters defining the positional relationship between the time zone and the time line measured in advance, which is stored in a predetermined storage unit included in the console, the athlete measures the time line from each detection time acquired by the time acquisition step. A time calculation step for calculating the time measured when passing through
A time measuring method comprising:

Images