Systems and methods for providing an ATC overlay data link
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01S-013/76
G01S-007/00
G01S-013/78
H04L-005/02
H04L-025/49
H04L-027/02
H04L-027/10
H04L-027/18
H04L-027/26
H04L-027/32
H04L-001/00
출원번호
US-0105248
(2008-04-17)
등록번호
US-9791562
(2017-10-17)
발명자
/ 주소
Stayton, Gregory T.
출원인 / 주소
Aviation Communication & Surveillance Systems, LLC
대리인 / 주소
Squire Patton Boggs
인용정보
피인용 횟수 :
0인용 특허 :
37
초록▼
Embodiments of the present invention disclose systems and methods for providing an ATC Overlay data link. Through embodiments of the present invention, existing ATC (or other) modulated signals using existing standard frequencies may be utilized to transmit (e.g., from an aircraft transponder) addit
Embodiments of the present invention disclose systems and methods for providing an ATC Overlay data link. Through embodiments of the present invention, existing ATC (or other) modulated signals using existing standard frequencies may be utilized to transmit (e.g., from an aircraft transponder) additional information in a manner that does not render the transmitted signal unrecognizable by legacy ATC equipment. Legacy equipment will be able to demodulate and decode information that was encoded in the transmitted signal in accordance with preexisting standard modulation formats, and updated equipment can also extract the additional information that was overlaid on transmitted signals.
대표청구항▼
1. A method for encoding an overlaid message onto a provided modulated air traffic control (ATC) signal, the method comprising: modulating respective pulse bits of the provided modulated ATC signal with an overlay message using D8PSK modulation, each respective phase change of the D8PSK modulation e
1. A method for encoding an overlaid message onto a provided modulated air traffic control (ATC) signal, the method comprising: modulating respective pulse bits of the provided modulated ATC signal with an overlay message using D8PSK modulation, each respective phase change of the D8PSK modulation encoding three bits of the overlay message within each respective pulse bit of the provided ATC signal, wherein the ATC signal is independently demodulatable from the overlay message. 2. The method as disclosed in claim 1, further comprising transmitting the overlay-modulated ATC signal from at least one of a TCAS transponder; an ADS-B transponder; a ATC radar; and a ground station. 3. The method as disclosed in claim 1, wherein the provided modulated ATC signal comprises a signal selected from the group consisting of: a transponder reply signal;a squitter signal;an ADS-B reply signal;a 1030 MHz interrogation signal;a 1030 MHz TCAS signal; bya General Aviation UAT transceiver signal on a UHF frequency band;at least one of a signal within a voice band or a data band operating within an ATC HF, VHF, and UHF band,a VDL Mode 4 ADS-B modulated signal;a DME signal;SATCOM signal;a signal originating from any avionics equipment that radiates a modulated RF signal;a baseband signal for transmitting data; andcombinations thereof. 4. The method as disclosed in claim 1 further comprising encrypting the overlay message. 5. The method as disclosed in claim 1 further comprising applying a second overlay modulation protocol to the overlay-modulated signal. 6. The method as disclosed in claim 5, wherein the second overlay modulation protocol is selected from the group consisting of: binary phase shift keying modulation (BPSK);quadrature phase shift keying modulation (QPSK);8-phase shift keying modulation (8-PSK);differential phase-shift keying (DPSK);DNPSK modulation, where N is an even integer and a multiple of 2;frequency shift keying (FSK);amplitude shift keying (ASK);quadrature amplitude modulation (QAM);orthogonal frequency-division multiplexing (OFDM);minimum-shift keying (MSK);asymmetric phase-shift keying, (APSK);pulse position modulation (PPM);amplitude modulation (AM);frequency modulation (FM); andcombinations thereof. 7. The method as disclosed in claim 5 wherein the second overlay modulation protocol is selected from the group consisting of: modulation by amplitude characteristics, modulation by phase characteristics, modulation by frequency characteristics, and any combination thereof. 8. The method as disclosed in claim 1 further comprising encoding, within the overlay message, at least one of: one or more parity bits;one or more CRC bits;Reed-Solomon bit error detection and correction data; andone or more error correction code bits. 9. A method for decoding an overlaid message from an overlay modulated signal, the method comprising: demodulating the overlay modulated signal with a first modulation protocol to produce a first message;demodulating the overlay modulated signal with D8PSK modulation to produce an overlay message comprising three bits of data for each bit of the first message; andwherein: the first message and the overlay message is independently demodulatable from the overlay modulated signal; andthe overlay modulated signal comprises an air traffic control (ATC) signal modulated with pulse position modulation protocol and further modulated with a D8PSK modulation protocol. 10. The method as disclosed in claim 9, further comprising receiving the overlay modulated signal in at least one of a TCAS transponder; an ADS-B transponder; an air traffic control (ATC) radar; and a ground station. 11. The method as disclosed in claim 9 further comprising decrypting the overlay message. 12. The method as disclosed in claim 9 further comprising demodulating the overlay modulated signal with a third modulation protocol, producing a second overlay message. 13. The method as disclosed in claim 12, wherein the third overlay modulation protocol is selected from the group consisting of: binary phase shift keying modulation (BPSK);quadrature phase shift keying modulation (QPSK);8-phase shift keying modulation (8-PSK);differential phase-shift keying (DPSK);DNPSK modulation, where N is an even integer and a multiple of 2;frequency shift keying (FSK);amplitude shift keying (ASK);quadrature amplitude modulation (QAM);orthogonal frequency-division multiplexing (OFDM);minimum-shift keying (MSK);asymmetric phase-shift keying, (APSK);pulse position modulation (PPM);amplitude modulation (AM);frequency modulation (FM);or any other modulation form using amplitude, phase, or frequency signal characteristics and methods of use; andcombinations thereof. 14. The method as disclosed in claim 12, wherein the third overlay modulation protocol is selected from the group consisting of: modulation by amplitude characteristics, modulation by phase characteristics, modulation by frequency characteristics, and any combination thereof. 15. The method as disclosed in claim 9 further comprising decoding the overlay message using at least one of: one or more parity bits;one or more CRC bits;Reed-Solomon bit error detection and correction data; andone or more error correction code bits. 16. An air traffic control (ATC) overlay data link system comprising: a first modulator, the first modulator configured to modulate ATC data into a first modulated signal through a first modulation protocol comprising pulse position modulation protocol;a second modulator coupled to the first modulator, the second modulator configured to modulate an overlay message into respective pulse bits of the first modulated signal using D8PSK modulation to produce an overlay modulated signal;a transponder comprising a transmitter and an antenna wherein the transponder is coupled to the second modulator and the transponder is configured to transmit the overlay modulated signal; anda receiver coupled to an antenna, a first demodulator and a second demodulator, wherein: the first demodulator is configured to extract the ATC data by demodulating the overlay modulated signal with the first modulation protocol;the second demodulator is configured to extract the overlaid message from an overlay modulated signal wherein each respective phase change of the D8PSK modulation represents three bits of the overlay message encoded within each respective pulse bit of the first modulated signal;the ATC data and the overlay message is independently demodulatable from the overlay modulated signal. 17. The ATC overlay data link system as disclosed in claim 16, wherein the second modulator is further configured to encode the overlay message using at least one of: one or more parity bits;one or more CRC bits;Reed-Solomon bit error detection and correction data; andone or more error correction code bits. 18. The ATC overlay data link system as disclosed in claim 16, wherein the receiver is further configured to decode the overlay message using at least one of: one or more parity bits;one or more CRC bits;Reed-Solomon bit error detection and correction data; andone or more error correction code bits. 19. The ATC overlay data link system as disclosed in claim 16 wherein the receiver is further configured to decode the overlay message, wherein the overlay message is recovered from data interleaved into message bit intervals within the overlay modulated signal. 20. The ATC overlay data link system as disclosed in claim 16, wherein the first modulated signal comprises a signal selected from the group consisting of: a transponder reply signal;a squitter signal;an ADS-B reply signal;a 1030 MHz interrogation signal;a 1030 MHz TCAS signal; bya General Aviation UAT transceiver signal on a UHF frequency band;at least one of a signal within a voice band or a data band operating within an ATC HF, VHF, and UHF band,a VDL Mode 4 ADS-B modulated signal;a DME signal;a SATCOM signal;a signal originating from any avionics equipment that radiates a modulated RF signal;a baseband signal for transmitting data; andcombinations thereof. 21. The ATC overlay data link system as disclosed in claim 16, wherein the second modulator is configured to apply the overlay modulation to one or more modulated message bit intervals within a data block in the first modulated signal. 22. The ATC overlay data link system as disclosed in claim 16, wherein the receiver comprises a receiver type selected from the group consisting of: a TCAS receiver; an ADS-B receiver; and a ground station receiver. 23. The ATC overlay data link system as disclosed in claim 16, wherein the transponder is selected from the group consisting of a TCAS transponder and an ADS-B transponder.
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