Abstract: A method for determining an optimal pulse repetition period (PRP) in a system including a wireless transmission device operating in a static physical transmission environment includes providing a first and second injection-locked transmission system (ILT system). The method further includes implementing an algorithm in a microprocessor within the first ILT system. The algorithm includes synchronizing a receiver clock in the second ILT system with the clock of the first ILT system; setting the PRP equal to an impulse duration, the PRP being very short; increasing the PRP until a bit error rate (BER) at the PRP is less than the bit error rate limit; and based on the determining that the BER is less than the bit error rate limit, setting the PRP as the optimal PRP.

Abstract: Methods and systems to modulate and demodulate first and second path bits within sequences of pulses, where each pulse represents first and second path bits and is position-modulated and phase-modulated based on binary values of the corresponding bits, with no more than 1 phase change per N pulses. Position-modulation may be based on first-path bits. Phase-modulation may be based on second-path bits. A modulator first path has an input data rate Q times that of a second path. The first may include an N-bit encoder. The second path may include a Q-bit encoder and an N-bit repetition encoder. A demodulator includes a first path to determine first path bit values based on pulse coordinates integrated over N frames, and a second path to determine second path bit values based on further integration over Q frames.

Abstract: Methods and systems to modulate and demodulate first and second path bits within sequences of pulses, where each pulse represents first and second path bits and is position-modulated and phase-modulated based on binary values of the corresponding bits, with no more than 1 phase change per N pulses. Position-modulation may be based on first-path bits. Phase-modulation may be based on second-path bits. A modulator first path has an input data rate Q times that of a second path. The first may include an N-bit encoder. The second path may include a Q-bit encoder and an N-bit repetition encoder. A demodulator includes a first path to determine first path bit values based on pulse coordinates integrated over N frames, and a second path to determine second path bit values based on further integration over Q frames.

Abstract: A method for determining an optimal pulse repetition period (PRP) in a system including a wireless transmission device operating in a static physical transmission environment includes providing a first and second injection-locked transmission system (ILT system). The method further includes implementing an algorithm in a microprocessor within the first ILT system. The algorithm includes synchronizing a receiver clock in the second ILT system with the clock of the first ILT system; setting the PRP equal to an impulse duration, the PRP being very short; increasing the PRP until a bit error rate (BER) at the PRP is less than the bit error rate limit; and based on the determining that the BER is less than the bit error rate limit, setting the PRP as the optimal PRP.