Lightweight image encryption for wireless sensor networks using optimized elliptic curve and fuzzy logic.
Mohsen Zarei, Mohammad Hosein Fatehi Dindarlou, Mehdi Taghizadeh, Jasem Jamali
Abstract
Open AccessWireless Sensor Networks face data breach risks due to resource-limited nodes and open environments. This clearly identifies the vulnerability of WSNs to data breaches, setting the context for the research. This study introduces a lightweight image encryption scheme. It describes the purpose of proposing a secure and efficient encryption method suitable for WSNs. It is also possible to create an encryption that is inaccessible even for simple images. Using dynamic S-boxes generated by elliptic curve cryptography and a fuzzy logic system optimized by the Wild Horse Optimization algorithm. A 256 × 256 hash-based key drives dynamic S-boxes, with fuzzy logic generating random sequences (0-255) for pixel permutation, substitution, XOR, and shift register operations. WHO-optimized fuzzy rules enable efficient, pixel-specific encryption without full ECC encoding. This describes the hybrid ECC-fuzzy logic-WHO approach, detailing key components and operations. Simulations show robust security with entropy ~ 7.9994, NPCR > 99.6%, UACI ~ 33.46%, inter-pixel correlation < 0.0024, and encryption time of 0.874s for 256 × 256 images. Resisting differential, statistical, and noise attacks, the method outperforms existing approaches with low computational overhead, making it ideal for WSNs.