TY - GEN
T1 - Receiver Algorithms to Approach the Quantum Limit of Demodulating Pulse Position Modulation
AU - Bia, Leo
AU - Gagatsos, Christos N.
AU - Guha, Saikat
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - Optical pulse position modulation (PPM) places a laser pulse, a.k.a. a coherent state of amplitude α of mean photon number N=|α|2, in one of M consecutive time slots, Ideal photon detection on each slot achieves a mean probability of error ((M-1)/1M)e-N of distinguishing the iM PPM codewords, since e-N is the probability the pulse-containing slot does not produce a click, per Poisson-shot-noise photo-detection theory. The quantum (Helstrom) limit of the minimum probability of error is lower than above, has a closed-form expression, and scales as ∼ e-2N when Me-N> 1. The optimal receiver must make a quantum joint measurement on all M slots. Even though receiver algorithms exist that achieve the ∼ e-2N scaling in the high N regime, none are known that bridge the classical-quantum gap for small N, the primary regime of interest for optical PPM. It is also not known how close to the Helstrom limit can one get using LOCC. (local operations and classical communications), i.e., a receiver that slices each of the M slots into n tiny slices, makes a measurement on the first slice, and based on the measurement result picks a measurement to apply to the next slice, etc., until all the Mn slices have been measured. In this paper, we propose an LOCC receiver for demodulating PPM that uses semiclassical coherent feedback control and photon detection, which outperforms all known PPM receivers, including one that employed squeezing, a non-classical operation. To bridge the remaining gap to the Helstrom limit, one might need truly quantum operations within a joint (non-LOCC) receiver.
AB - Optical pulse position modulation (PPM) places a laser pulse, a.k.a. a coherent state of amplitude α of mean photon number N=|α|2, in one of M consecutive time slots, Ideal photon detection on each slot achieves a mean probability of error ((M-1)/1M)e-N of distinguishing the iM PPM codewords, since e-N is the probability the pulse-containing slot does not produce a click, per Poisson-shot-noise photo-detection theory. The quantum (Helstrom) limit of the minimum probability of error is lower than above, has a closed-form expression, and scales as ∼ e-2N when Me-N> 1. The optimal receiver must make a quantum joint measurement on all M slots. Even though receiver algorithms exist that achieve the ∼ e-2N scaling in the high N regime, none are known that bridge the classical-quantum gap for small N, the primary regime of interest for optical PPM. It is also not known how close to the Helstrom limit can one get using LOCC. (local operations and classical communications), i.e., a receiver that slices each of the M slots into n tiny slices, makes a measurement on the first slice, and based on the measurement result picks a measurement to apply to the next slice, etc., until all the Mn slices have been measured. In this paper, we propose an LOCC receiver for demodulating PPM that uses semiclassical coherent feedback control and photon detection, which outperforms all known PPM receivers, including one that employed squeezing, a non-classical operation. To bridge the remaining gap to the Helstrom limit, one might need truly quantum operations within a joint (non-LOCC) receiver.
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U2 - 10.1109/ISIT57864.2024.10619446
DO - 10.1109/ISIT57864.2024.10619446
M3 - Conference contribution
AN - SCOPUS:85202852716
T3 - IEEE International Symposium on Information Theory - Proceedings
SP - 795
EP - 800
BT - 2024 IEEE International Symposium on Information Theory, ISIT 2024 - Proceedings
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2024 IEEE International Symposium on Information Theory, ISIT 2024
Y2 - 7 July 2024 through 12 July 2024
ER -