Synchronization of spatiotemporal semiconductor lasers and its application in color image encryption

TL;DR

This paper explores the synchronization of spatiotemporal semiconductor lasers and applies this high-dimensional chaos to develop a robust, two-phase color image encryption scheme with high security and resistance to attacks.

Contribution

It introduces a novel laser synchronization system and demonstrates its application in a secure, two-phase image encryption method utilizing chaotic sequences for enhanced cryptographic properties.

Findings

High-dimensional chaotic attractor enables effective encryption

The scheme is robust against noise and common cryptographic attacks

Encryption significantly alters original image statistics

Abstract

Optical chaos is a topic of current research characterized by high-dimensional nonlinearity which is attributed to the delay-induced dynamics, high bandwidth and easy modular implementation of optical feedback. In light of these facts, which adds enough confusion and diffusion properties for secure communications, we explore the synchronization phenomena in spatiotemporal semiconductor laser systems. The novel system is used in a two-phase colored image encryption process. The high-dimensional chaotic attractor generated by the system produces a completely randomized chaotic time series, which is ideal in the secure encoding of messages. The scheme thus illustrated is a two-phase encryption method, which provides sufficiently high confusion and diffusion properties of chaotic cryptosystem employed with unique data sets of processed chaotic sequences. In this novel method of cryptography, the chaotic phase masks are represented as images using the chaotic sequences as the elements of the image. The scheme drastically permutes the positions of the picture elements. The next additional layer of security further alters the statistical information of the original image to a great extent along the three-color planes. The intermediate results during encryption demonstrate the infeasibility for an unauthorized user to decipher the cipher image. Exhaustive statistical tests conducted validate that the scheme is robust against noise and resistant to common attacks due to the double shield of encryption and the infinite dimensionality of the relevant system of partial differential equations.