초록 ▼

To reduce radar cells and to improve the detection of a radar system, particularly a high-frequency surface wave radar (HFSWR), the broadcast system (SEM) is capable of broadcasting basic orthogonal signals two by two and each orthogonal to itself, temporally shifted to form, respectively, broadcast

To reduce radar cells and to improve the detection of a radar system, particularly a high-frequency surface wave radar (HFSWR), the broadcast system (SEM) is capable of broadcasting basic orthogonal signals two by two and each orthogonal to itself, temporally shifted to form, respectively, broadcast radiation patterns, each including main radiation lobes (LP1, LPN) alternating with secondary lobes, the main lobes associated with the basic signals being substantially juxtaposed in space. The receiving system (SRE) is capable of forming as many reception patterns in a monitored receiving area (ZR) as cells (CESn'm) contained in the receiving area that are covered by main radiation lobes (LPn) from one of the broadcast radiation patterns and located at a bistatic distance from the broadcast and receiving systems.

대표청구항 ▼

1. A method for remote sensing using: an emission system comprising a plurality of emission antennas for emitting a plurality of signals, wherein:each of the emitted signals results from modulation of a carrier signal by an encoded sequence,the encoded sequence of each emitted signal is orthogonal t

1. A method for remote sensing using: an emission system comprising a plurality of emission antennas for emitting a plurality of signals, wherein:each of the emitted signals results from modulation of a carrier signal by an encoded sequence,the encoded sequence of each emitted signal is orthogonal to the encoded sequence of any other emitted signal,the encoded sequence of each emitted signal is orthogonal to the encoded sequence of another instance of the emitted signal with a non-zero offset in time, andeach emission of a respective signal is made by the antennas with a preset signal strength distribution according to an emission radiation chart, the emission radiation chart including main radiation lobes indicating maximum signal strength alternating with secondary radiation lobes indicating minimum signal strength, anda reception system comprising a plurality of reception antennas for receiving signals emitted by the plurality of emission antennas, wherein each reception of a respective signal is made by antennas in a reception area according to a reception radiation chart;the method comprising:emitting the plurality of signals by the emission antennas according to the emission radiation chart defining signal strength distribution of the signals, wherein the main radiation lobes of the emission radiation charts of the respective signals are arranged together in space one by one in a laminated pattern;receiving signals by the reception antennas according to a reception radiation chart indicating a reception area and relationship between the reception area and the main radiation lobes;detecting a number of radio cells which are: contained in the reception area,covered by the main radiation lobes of one of the emission radiation charts, andlocated at a given bistatic distance from the emission system and the reception system;wherein the detecting of the number of the radio cells comprises:weighting the signals received by the reception antennas; andon the basis of the received signals and on a bistatic distance of the set of weighted signals, identifying cells having a constant bistatic distance and, for a given distance, cells associated with one of the received signals which can be distinguished one from another at least by their encoded sequences being orthogonal to each other. 2. The method according to claim 1, further comprising successively and cyclically emitting the plurality of signals. 3. The method according to claim 1, wherein each emission radiation chart has a plurality of main lobes corresponding to surface density maximums of radiated energy alternating with secondary radiation lobes corresponding to surface density minimums of radiated energy. 4. The method according to claim 1, wherein at least one of the amplitude and phase of the emitted signal is adjusted according to a weighting coefficient. 5. A remote sensing system for remote sensing, comprising: an emission system having a plurality of emission antennas for emitting a plurality of signals, wherein:each of the emitted signals results from modulation of a carrier signal by an encoded sequence,the encoded sequence of each emitted signal is orthogonal to the encoded sequence of any other emitted signal, andthe encoded sequence of each emitted signal is orthogonal to the encoded sequence of another instance of the emitted signal with a non-zero offset in time;wherein the emission system is configured to emit the plurality of signals by the emission antennas with a preset signal strength distribution according to an emission radiation chart, wherein the emission radiation chart includes main radiation lobes indicating maximum signal strength alternating with secondary radiation lobes indicating minimum signal strength; and the main radiation lobes of the emission radiation charts of the respective signals are arranged together in space one by one in a laminated pattern; anda reception system having a plurality of reception antennas for receiving the signals emitted by the plurality of emission antennas, wherein the reception system is configured to:receive the emitted signals by the reception antennas according to a reception radiation chart indicating at least one reception area and relationship between the reception area and the main radiation lobes;detect a number of radio cells which are: contained in the reception area,covered by the main radiation lobes of one of the emission radiation charts, andlocated at a given bistatic distance from the emission system and the reception system;wherein the detecting of the number of the radio cells comprises:weighting the signals received by the reception antennas; andon the basis of the received signals and on a bistatic distance of the set of weighted signals, identifying radio cells having a constant bistatic distance and, for a given bistatic distance, radio cells associated with one of the received signals which can be distinguished one from another at least by their encoded sequences being orthogonal to each other. 6. The remote sensing system of claim 5, wherein each emission radiation chart has a plurality of main lobes corresponding to surface density maximums of radiated energy alternating with secondary radiation lobes corresponding to surface density minimums of radiated energy. 7. The remote sensing system of claim 5, wherein at least one of an amplitude and phase of the emitted signal is adjusted according to a weighting coefficient. 8. The remote sensing system of claim 5, wherein the plurality of signals are emitted successively and cyclically. 9. A non-transitory computer-readable medium having instructions stored thereon, which, when executed by at least one processor, cause the at least one processor to cause a remote sensing system including an emission system and a reception system to perform the steps of: emitting a plurality of signals by a plurality of emission antennas in the emission system with a preset signal strength distribution according to an emission radiation chart, wherein:each of the emitted signals results from modulation of a carrier signal by an encoded sequence,the encoded sequence of each emitted signal is orthogonal to the encoded sequence of any other emitted signal,the encoded sequence of each emitted signal is orthogonal to the encoded sequence of another instance of the emitted signal with a non-zero offset in time, andthe emission radiation chart includes main radiation lobes indicating maximum signal strength alternating with secondary radiation lobes indicating minimum signal strength; and the main radiation lobes of the emission radiation charts of the respective signals are arranged together in space one by one in a laminated pattern; andreceiving the emitted signals by a plurality of reception antennas in the reception system according to a reception radiation chart indicating at least one reception area and relationship between the reception area and the main radiation lobes;detecting a number of radio cells which are: contained in the reception area,covered by the main radiation lobes of one of the emission radiation charts, andlocated at a given bistatic distance from the emission system and the reception system;wherein the detecting of the number of the radio cells comprises:weighting the signals received by the reception antennas; andon the basis of the received signals and on a bistatic distance of the set of weighted signals, identifying radio cells having a constant bistatic distance and, for a given bistatic distance, radio cells associated with one of the received signals which can be distinguished one from another at least by their encoded sequences being orthogonal to each other. 10. The non-transitory computer-readable medium according to claim 9, wherein at least one of the amplitude and phase of the emitted signal is adjusted according to a weighting coefficient. 11. The non-transitory computer-readable medium according to claim 9, wherein each emission radiation chart has a plurality of main lobes corresponding to surface density maximums of radiated energy alternating with secondary radiation lobes corresponding to surface density minimums of radiated energy. 12. The non-transitory computer-readable medium according to claim 9, wherein the plurality of signals are emitted successively and cyclically.