Schmidt-Langhorst, C.C.Schmidt-LanghorstPfeiffer, J.J.PfeifferElschner, R.R.ElschnerFrey, F.F.FreyEmmerich, R.R.EmmerichFischer, R.F.H.R.F.H.FischerSchubert, C.C.Schubert2022-03-152022-03-152019https://publica.fraunhofer.de/handle/publica/4121012-s2.0-85096500969In optical transmission systems, security against eavesdroppers is of increasing importance. Following the concept of physical-layer security, we experimentally quantify the security gap that can be achieved when applying punctured low-density parity-check (LDPC) codes for various modulation schemes and bit rates in a state-of-the art laboratory coherent optical communication system. We examine operating points at gross bit-rates up to 768 Gb/s using up to 64.0-GBd dual-polarization (DP) 64-ary quadrature amplitude modulation (QAM) in combination with bit-interleaved coded modulation (BICM). We find that security gaps ranging from 5.6 dB for a net secure data rate of 76.2 Gb/s (32-GBd DP-QAM04) up to 10.7 dB for 457 Gb/s (64-GBd DP-QAM64) are required for the legitimate receiver over the eavesdropper. For the low-cardinality DP-QAM04 format the required security gap is mainly equal to the theoretically achievable minimum security gap. However, with increasing cardinalit y of the modulation format, the practical implementation penalty accounts for a significant portion of the security gap of up to an additional 3.7 dB at 64-GBd DP-QAM64.en621conference paper