Secure Communications using Nonlinear Silicon Photonic Keys

TL;DR

This paper introduces a secure communication system utilizing nonlinear silicon photonic PUFs that generate large, complex keys from micro-cavities, enabling high-security data exchange without digital key transmission.

Contribution

The work demonstrates a novel silicon photonic PUF-based secure communication method capable of extracting 2.4 Gb of key material and achieving low error rates, with practical advantages over traditional systems.

Findings

Extracted 2.4 Gb of key material from a single micro-cavity.

Achieved bit error rates below 10^-5 at 0.1 code rate.

System is small, inexpensive, and compatible with existing telecom infrastructure.

Abstract

We present a secure communication system constructed using pairs of nonlinear photonic physical unclonable functions (PUFs) that harness physical chaos in integrated silicon micro-cavities. Compared to a large, electronically stored one-time pad, our method provisions large amounts of information within the intrinsically complex nanostructure of the micro-cavities. By probing a micro-cavity with a rapid sequence of spectrally-encoded ultrafast optical pulses and measuring the lightwave responses, we experimentally demonstrate the ability to extract 2.4 Gb of key material from a single micro-cavity device. Subsequently, in a secure communications experiment with pairs of devices, we achieve bit error rates below $10^{-5}$ at code rates of up to 0.1. The PUFs' responses are never transmitted over the channel or stored in digital memory, thus enhancing security of the system. Additionally, the micro-cavity PUFs are extremely small, inexpensive, robust, and fully compatible with telecommunications infrastructure, components, and electronic fabrication. This approach can serve one-time pad or public key exchange applications where high security is required