A method for a distributed clock system (DCS) device that includes receiving a GPS signal, determining that a first current time equals a predetermined start time, and generating a shifted GPS signal by applying a configurable delay to the received GPS signal, the shifted GPS signal alternating between a low value and a high value. The method includes responsive to a falling edge of the shifted GPS signal, generating an ARM signal having a rising edge after a falling edge of the shifted GPS signal, and responsive to the ARM signal being high and the shifted GPS signal being high, generating an output enable signal. The method includes transmitting, while the output enable signal is high, a triggering signal, the triggering signal having one or more synchronizing pulses that cause one or more sampling devices to sample data according to the frequency associated with the raw clock signal.

A method for a distributed clock system (DCS) device that includes receiving a GPS signal, determining that a first current time equals a predetermined start time, and generating a shifted GPS signal by applying a configurable delay to the received GPS signal, the shifted GPS signal alternating between a low value and a high value. The method includes responsive to a falling edge of the shifted GPS signal, generating an ARM signal having a rising edge after a falling edge of the shifted GPS signal, and responsive to the ARM signal being high and the shifted GPS signal being high, generating an output enable signal. The method includes transmitting, while the output enable signal is high, a triggering signal, the triggering signal having one or more synchronizing pulses that cause one or more sampling devices to sample data according to the frequency associated with the raw clock signal.

The system and method of weapon on-board range and velocity tracking using a synchronized clock and a pulse beacon on a fire control system, or the like, coupled with an on-board rear-facing detector and processor. A round or a UAS may use this system to accurately estimate range with respect to the fire control system, over time, and the round's or UAS's velocity at various times along its flight path. The system provides for smaller miss distances, and the like.

The system and method of weapon on-board range and velocity tracking using a synchronized clock and a pulse beacon on a fire control system, or the like, coupled with an on-board rear-facing detector and processor. A round or a UAS may use this system to accurately estimate range with respect to the fire control system, over time, and the round's or UAS's velocity at various times along its flight path. The system provides for smaller miss distances, and the like.

A method, apparatus, and system are provided for facilitating positioning based on signal correlation function characteristic feedback. In an embodiment, the method may involve steps performed by a network node in communication with a wireless communication device (WCD) and a plurality of base stations. The network node receives, from the WCD, location information including position reference signal (PRS) correlation function characteristics of a cross-correlation between a received downlink signal and a transmitted PRS for each base station from the plurality of base stations. The network node determines a position of the WCD using the PRS correlation function characteristics. The WCD may initiate the transmission of the PRS correlation function characteristics on its own, or in response to a request to do so from the network node.

Solid-state miniature atomic clock (SMAC) within the form factor of an integrated circuit chip (aka microchip) or flexible device. The present invention includes architectures and methods of manufacture of SMACs. SMACs may include one or more vias, with some or all of the vias containing or other material suitable for an antenna. In addition, the SMAC may include a heating device for temperature stabilization.

The invention relates to a method for determining a distance using a high-resolution method based on signal propagation time measurements. The process of determining distances from wireless signals with a high degree of precision using mathematical methods is known, for example using MUSIC or CAPON or methods such as those from EP 3 564 707, EP 3 502 736 A1, or EP 2 212 705. These methods, however, normally require phase measurements. The aim of the invention is to allow such methods to be used even purely with propagation time measurements. This is achieved in that complex numbers are constructed from propagation time measurements and amplitude mea-surements or power measurements, said complex numbers allowing the use of known methods.

The invention relates to a method for determining a distance using a high-resolution method based on signal propagation time measurements. The process of determining distances from wireless signals with a high degree of precision using mathematical methods is known, for example using MUSIC or CAPON or methods such as those from EP 3 564 707, EP 3 502 736 A1, or EP 2 212 705. These methods, however, normally require phase measurements. The aim of the invention is to allow such methods to be used even purely with propagation time measurements. This is achieved in that complex numbers are constructed from propagation time measurements and amplitude mea-surements or power measurements, said complex numbers allowing the use of known methods.

Method for secure distance measurement comprising the following steps: transmitting from a verifier (V) to a prover (P) a challenge message comprising a challenge bit sequence (C); transmitting from the prover (P) to the verifier (V) a response message comprising the response bit sequence (R); verifying, in the verifier (V), the response message on the basis of the response bit sequence (R); and determining, in the verifier (V), the distance between the verifier (V) and the prover (P) on the basis of the time difference between the challenge message and the response message. The challenge message and/or the response message are transmitted by a transmission protocol in which the bit sequence (C, R) of the corresponding message is transmitted by a transformed spreading code chip sequence (TCSCS, TRSCS), wherein the transformed spreading code chip sequence (TCSCS, TRSCS) is obtained by transforming a spreading code chip sequence (CSCS, RSCS) of the bit sequence (C, R) on the basis of a transform function (f.sub.trans).

Method for secure distance measurement comprising the following steps: transmitting from a verifier (V) to a prover (P) a challenge message comprising a challenge bit sequence (C); transmitting from the prover (P) to the verifier (V) a response message comprising the response bit sequence (R); verifying, in the verifier (V), the response message on the basis of the response bit sequence (R); and determining, in the verifier (V), the distance between the verifier (V) and the prover (P) on the basis of the time difference between the challenge message and the response message. The challenge message and/or the response message are transmitted by a transmission protocol in which the bit sequence (C, R) of the corresponding message is transmitted by a transformed spreading code chip sequence (TCSCS, TRSCS), wherein the transformed spreading code chip sequence (TCSCS, TRSCS) is obtained by transforming a spreading code chip sequence (CSCS, RSCS) of the bit sequence (C, R) on the basis of a transform function (f.sub.trans).