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A method and devices are disclosed, for tracking a radio beacon from a moving device, while the beacon transmits periodic signals, which the device detects at least at two different locations, and the device provided with information enabling determining the time difference between transmissions of

A method and devices are disclosed, for tracking a radio beacon from a moving device, while the beacon transmits periodic signals, which the device detects at least at two different locations, and the device provided with information enabling determining the time difference between transmissions of these periodic signals. The method discloses a formula for estimating the angle between the course of the moving device and the beacon: arccos c*(TDOA12−TDOT12)/baseline12; wherein the moving device detects signal 1 and signal 2 respectively at location 1 and location 2, the distance between these locations defined as baseline12, TDOA12 is the Time Difference of Arrival of the signals at the two locations, TDOT12 is the time difference between transmission of these signals, and c is the speed of light.

대표청구항 ▼

1. A method for tracking a radio beacon from a moving device, comprising the steps of: a. at said radio beacon transmitting periodic signals;b. providing said device with information enabling determining at least a time difference TDOT12 between a transmission time instant of a first signal and a tr

1. A method for tracking a radio beacon from a moving device, comprising the steps of: a. at said radio beacon transmitting periodic signals;b. providing said device with information enabling determining at least a time difference TDOT12 between a transmission time instant of a first signal and a transmission time instant of a second signal, said first and second signals been part of said periodic signals;c. at said device, at a first location, determining location coordinates, and a receiving time instant of said first signal;d. at said device, at a second location, determining location coordinates, and a receiving time instant of said second signal;e. at said device, determining a time difference TDOA12 between the receiving time instant of said first signal and the receiving time instant of said second signal, and a distance baseline12 between said first and second locations;f. at said device, determining a direction to said radio beacon, from said TDOT12, TDOA12 and baseline12. 2. The method according to claim 1, wherein said information is associated with at least one of: a. data configured in advance at said beacon and at said device;b. data communicated from said beacon to said device;c. data specifying TDOT12;d. minimum time difference (ΔT) between permitted values of TDOT12;e. time of transmission with respect to a beacon time reference;f. time of transmission with respect to a time reference known to said device;g. time between a predefined phase of said time reference known to said device and time of transmission;h. maximum operating range;i. maximum length of baseline12. 3. The method according to claim 1, at said device, estimating the direction from said second location to said beacon, relatively to the direction from said first location to said second location, as an angle of: arccos [c*(TDOA12−TDOT12)/baseline12]; wherein c is the speed of light. 4. The method according to claim 1, at said device, for moving towards the beacon, at said first location, determining the direction to a second location such that [baseline12−c*(TDOA12−TDOT12)] is zero. 5. The method according to claim 1, at said device, further comprising the steps of: a. providing information enabling determining a time difference TDOT34 between transmission of a third signal and a forth signal, of said periodic signals;b. at a third location, determining location coordinates, and a receiving time instant of said third signal;c. at a forth location, determining location coordinates, and a receiving time instant of said forth signal;d. determining a time difference TDOA34 between said receiving time instant of said third signal and said receiving time instant of said forth signal, and determining a distance baseline34 between said third location and said forth location;e. determining the location of said radio beacon, from said TDOT12, TDOA12, baseline12, TDOT34, TDOA34 and baseline34. 6. The method according to claim 1, wherein the period of said periodic signals is an integer number multiplied by ΔT, wherein ΔT is greater than at least one of: a. the maximum operating range divided by the speed of light;b. the maximum length of baseline12 divided by the speed of light. 7. The method according to claim 1, wherein said transmission time instants and receiving time instants are determined with respect to a same time reference. 8. The method according to claim 7, further comprising the steps of: a. at said beacon, determining the transmission time of said first signal and second signal with respect to a predefined phase of said same time reference;b. at said device, determining the location of said radio beacon from: said coordinates at said first and second locations, and the receiving time instant of said first and second signal, and said predefined phase of said same time reference. 9. A portable device for tracking a radio beacon, said device comprising: a first receiver, a GNSS receiver, a computer and an indicator; said device configured with at least two operating modes: acquisition and tracking; in acquisition mode, said device configured to determine initial geolocation coordinates of said beacon, and in tracking mode said device configured to determine a direction to said beacon while moving substantially in said direction; said device configured to detect signals periodically transmitted by said radio beacon and to accurately measure time of reception of said signals, and provided with information enabling determining at least a time difference TDOT12 between transmission of a first signal and transmission of a second signal, of said periodic signals; and determine, at a first location, location coordinates, and a receiving time of said first signal; and determine, at a second location, location coordinates, and a receiving time of said second signal; and determine a time difference TDOA12 between said receiving time of said first and said second signal, and determine a distance baseline12 between said first location and said second location; and determine a direction to said radio beacon, based on said TDOT12, TDOA12 and baseline12; and indicate said direction to a user. 10. The device according to claim 9, wherein said information is associated with at least one of: a. data configured in advance at said beacon and at said device;b. data communicated from said beacon to said device;c. data specifying TDOT12;d. minimum time difference (ΔT) between permitted values of TDOT12;e. time of transmission with respect to the beacon time reference;f. time of transmission with respect to a time reference known to said device;g. time between a predefined phase of said time reference known to said device and time of transmission;h. maximum operating range;i. maximum length of baseline12. 11. The device according to claim 9, further configured to estimate the direction from said second location to said beacon, relatively to the direction from said first location to said second location, as an angle of: arccos [c*(TDOA12−TDOT12)/baseline12]; wherein c is speed of light. 12. The device according to claim 9, further configured, in tracking mode, for a given first location, to determine the direction to a second location such that [baseline12−c*(TDOA12−TDOT12)] is zero. 13. The device according to claim 9, further in acquisition mode, provided with information enabling determining a time difference TDOT34 between transmission of a third signal and a forth signal, of said periodic signals; and configured to determine, at a third location, location coordinates, and receiving time of said third signal; and to determine at a forth location, location coordinates, and receiving time of said forth signal; and determine a time difference TDOA34 between said receiving time of said third signal and forth signal, and a distance baseline34 between said third location and said forth location; and determine a location of said radio beacon, from said TDOT12, TDOA12, baseline12, TDOT34, TDOA34 and baseline34. 14. The device according to claim 9, wherein the period of said periodic signals is an integer number times ΔT, wherein ΔT is greater than at least one of: a. a maximum operating range divided by the speed of light;b. the maximum length of baseline12 divided by the speed of light. 15. The device according to claim 9, wherein said transmission time instants and receiving time instants are determined with respect to a same time reference. 16. The device according to claim 15, wherein said transmission time of said first signal and second signal are determined with respect to a predefined phase of said same time reference, and said device configured to determine a location of said radio beacon, from coordinates at said first and second locations, and the receiving time instant of said first and second signal, and said predefined phase of said same time reference. 17. A radio beacon comprising an accurate clock generator, a data processor and a carrier frequency generator, enabling tracking by a moving device, the beacon configured to transmit periodic signals at timing controlled by said clock generator, wherein a time difference between transmissions of at least two of said signals configured substantially equal to m times ΔT, and wherein m is an integer number, and ΔT is greater than at least one of: a. a maximum specified range between said beacon and said device, divided by the speed of light;b. a maximum distance between locations where said two signals are detected, divided by the speed of light;enabling said device determining a direction to said beacon from said m and ΔT, and from time measured between detecting said two signals, each signal detected at a different location, and from distance measured between said different locations. 18. The radio beacon according to claim 17, said signals modulated according to a direct sequence spread spectrum (DSSS) scheme. 19. The radio beacon according to claim 17, further comprising a GNSS receiver, and configured to determine the transmission time of said two signals with respect to a predefined phase of a clock synchronized with said GNSS clock. 20. The radio beacon according to claim 19, wherein the time period of said clock synchronized with said GNSS clock is not shorter than a maximum specified range between said beacon and said device, divided by the speed of light.