Abstract

We present a real-world Gigabit Passive Optical Network (GPON)-based Fiber to the Home (FTTH) network serving up to 32 users, installed in COSMOTE laboratories in Athens. The deployment relies on the use of fiber optics and GPON telecom equipment which are identical to those found in the currently deployed FTTH infrastructure. We describe real-life network designs that correspond to specific installations considered in Athens urban metropolitan area. We propose a practical upstream Quantum Access Network (QAN) over the installed FTTH network, relied on a centralized quantum receiver (Bob) station located at the operator's Central Office, which exploits the Time-Division Multiplexing (TDM) framing technique to receive single-photons from multiple independent quantum transmitters (Alice) located at users premises. This integration scheme is characterized by performing a series of noise measurements at single-photon level to evaluate the potential of the coexistence of classical/quantum links on the same fiber cores. The noise count rates are found to follow the Raman noise profile for specified values of effective Raman cross-sections of downstream and upstream GPON data channels. Subsequently, the experimental results are exploited to evaluate the performance of the widely-used Coherent One Way (COW) Quantum Key Distribution (QKD) protocol. The presented simulation results for the quantum layer suggest the feasibility of our integration scheme for short feeder fiber segments. Finally, the dependance of the Secure Key Rate (SKR) on the network capacity is also discussed.