Integrating Lorenz Hyperchaotic Encryption with Ring Oscillator Physically Unclonable Functions (RO-PUFs) for High-Throughput Internet of Things (IoT) Applications

Abstract: With the combined call for increased network throughput and security comes the need for high-bandwidth, unconditionally secure systems. Through the combination of true random number generators (TRNGs) for unique seed values, and four-dimensional Lorenz hyperchaotic systems implemented on a Stratix 10 Intel FPGA, we are able to implement 60 MB/s encryption/decryption schemes with 0% data loss on an unconditionally secure system with the NIST standard using less than 400 mW. Further, the TRNG implementation allo… Show more

“…Integrating chaotic signals with coherent modulation techniques enhances security in IoT systems [15]. These signals find applications in fields like random number generation [16,17], encryption [18][19][20][21], radar systems [22][23][24], and IoT communications [25][26][27]. The versatility of chaotic signals in generating analog signals and digital logistic maps drives interest, particularly in FPGAbased image encryption using chaotic logistic maps [28][29][30].…”

Experimental Study on Colpitts Chaotic Oscillator-Based Communication System Application for the Internet of Things

“…Integrating chaotic signals with coherent modulation techniques enhances security in IoT systems [15]. These signals find applications in fields like random number generation [16,17], encryption [18][19][20][21], radar systems [22][23][24], and IoT communications [25][26][27]. The versatility of chaotic signals in generating analog signals and digital logistic maps drives interest, particularly in FPGAbased image encryption using chaotic logistic maps [28][29][30].…”

Experimental Study on Colpitts Chaotic Oscillator-Based Communication System Application for the Internet of Things

Post-Quantum SecureSensor Networks: Combining Ascon and SPHINCS+