Signals, systems and methods for transmitting and receiving layered modulation for digital signals are presented. A layered signal for transmitting data, comprises a first signal layer including a first carrier and first signal symbols for a first digital signal transmission and a second signal laye
Signals, systems and methods for transmitting and receiving layered modulation for digital signals are presented. A layered signal for transmitting data, comprises a first signal layer including a first carrier and first signal symbols for a first digital signal transmission and a second signal layer including a second carrier and second signal symbols for a second signal transmission disposed on the first signal layer, wherein the layered signal has the first carrier demodulated and first layer decoded to produce the first signal symbols for a first layer transport, the first signal symbols are remodulated and subtracted from the layered signal to produce the second signal layer, and the second signal layer has the second carrier demodulated and decoded to produce the second signal symbols for a second layer transport.
대표청구항▼
What is claimed is: 1. A method of transmitting a transmission signal having a legacy upper layer signal and a lower layer signal non-coherently added to the legacy upper layer signal, the method comprising: transmitting the legacy upper layer signal including a first carrier and first signal symbo
What is claimed is: 1. A method of transmitting a transmission signal having a legacy upper layer signal and a lower layer signal non-coherently added to the legacy upper layer signal, the method comprising: transmitting the legacy upper layer signal including a first carrier and first signal symbols; and transmitting a lower layer signal including a second carrier and second signal symbols; wherein a plurality of legacy receivers demodulate the legacy upper layer signal to produce the first signal symbols and do not demodulate the lower layer signal to produce the second signal symbols; and wherein a plurality of layered modulation receivers demodulate the legacy upper layer signal to produce the first signal symbols, remodulate the first signal symbols, and subtract the remodulated first signal symbols from the demodulated legacy upper layer signal to produce the second signal symbols. 2. The method of claim 1, wherein at least one of the legacy upper layer signal and the lower layer signal are quadrature phase shift keyed (QPSK). 3. The method of claim 1, wherein a code rate for at least one of the legacy upper layer signal and lower layer signal is 6/7. 4. The method of claim 1, wherein a code rate for at least one of the legacy upper layer signal and lower layer signal is 2/3. 5. The method of claim 1, wherein a code rate for at least one of the legacy upper layer signal and lower layer signal is 1/2. 6. The method of claim 1, wherein the lower layer signal is generated by power boosting a legacy signal. 7. The method of claim 1, wherein a total code and noise level of the legacy upper layer signal is no greater than a noise floor of the second signal layer. 8. The method of claim 1, wherein at least one of the legacy upper layer signal and lower layer signal is coded using a turbo code. 9. The method of claim 1, wherein both the legacy upper layer signal and lower layer signal are coded using a single turbo code. 10. A receiver system for compatibly receiving a transmission signal having a legacy upper layer signal and a lower layer signal non-coherently added to the legacy upper layer signal, the system comprising: a plurality of layered modulation receivers, each comprising; a first demodulator for demodulating the legacy upper layer signal to produce a demodulated signal; a first layer decoder, coupled to the first layer demodulator, for decoding the demodulated signal to produce legacy upper layer signal symbols; a remodulator, coupled to the first layer decoder, for remodulating the first signal symbols to produce a remodulated legacy upper layer signal; a subtracter, coupled to the first demodulator and the remodulator, for subtracting the remodulated legacy upper layer signal from the demodulated signal to produce the lower layer signal; a second layer demodulator, coupled to the subtracter, the second layer demodulator for demodulating the lower layer signal to produce a second demodulator output; and a second layer decoder, coupled to the second layer demodulater, the second layer decoder for decoding the second layer demodulated output to produce lower layer signal symbols; a plurality of legacy receivers, each configured to demodulate the legacy upper layer signal and not the lower layer signal, and each comprising: a legacy receiver demodulator configured to demodulate the legacy upper layer signal to produce a second demodulated signal; and a legacy receiver decoder, coupled to the legacy receiver demodulator, configured to decode the second demodulated signal to produce legacy upper layer symbols. 11. The receiver system of claim 10, further comprising a non-linear distortion map for removing non-linear distortion effects from the remodulated legacy upper layer signal. 12. The receiver system of claim 10, wherein the legacy upper layer signal is a boosted legacy signal. 13. The receiver system of claim 10, wherein at least one of the legacy upper layer signal and lower layer signal are quadrature phase shift keyed (QPSK). 14. The receiver system of claim 10, wherein a code rate for at least one of the legacy upper layer signal and lower layer signal is 6/7. 15. The receiver system of claim 10, wherein a code rate for at least one of the legacy upper layer signal and lower layer signal is 2/3. 16. The receiver system of claim 10, wherein a code rate for at least one of the legacy upper layer signal and lower layer signal is 1/2. 17. The receiver system of claim 10, wherein the second signal layer is generated by power boosting the legacy upper layer signal. 18. The receiver system of claim 10, wherein a total code and noise level of the legacy upper layer signal is no greater than a noise foor of the lower layer signal. 19. The receiver system of claim 10, wherein at least one of the legacy upper layer signal and lower layer signal is coded using a turbo code. 20. The receiver system of claim 10, wherein both the legacy upper layer signal and lower layer signal are coded using a single turbo code. 21. The receiver system of claim 10, wherein the legacy upper layer signal and lower layer signal each have a carrier frequency that is substantially similar. 22. The receiver system of claim 10, wherein a carrier frequency of the legacy upper layer signal and a second carrier frequency of the lower layer signal are offset in frequency. 23. The receiver system of claim 10, wherein the first layer decoder comprises a Viterbi decoder. 24. The receiver system of claim 10, wherein the first layer decoder comprises a Reed-Solomon decoder.
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