- Quantum eMotion (OTCQB: QNCCF) announces the successful completion of its quantum simulation project evaluating the Sentry-Q cryptographic architecture.
- Simulations show Grover's algorithm's success rate decreases significantly with larger key sizes, enhancing security against quantum attacks.
- Future plans include hybrid testbenches and real-time emulation of cryptographic architectures with QRNG integration under constrained computing conditions.
Quantum eMotion Corp. (OTCQB: QNCCF) has completed an internal quantum simulation project that examines its Sentry-Q cryptographic architecture. Conducted in collaboration with PINQ², the project used IBM's Qiskit framework to simulate Grover's algorithm, which is known for its potential ability to expedite brute-force attacks on symmetric encryption schemes.
The study's key findings reveal that Grover's algorithm's success rate is significantly reduced with larger key sizes. At projected real-world key sizes, such as 256 bits, the algorithm would require approximately 2^128 iterations to succeed, rendering these attacks impractical with current quantum hardware. This enhancement in security is attributed to the integration of QeM's proprietary Quantum Random Number Generator (QRNG), which increases oracle complexity and circuit depth in simulated quantum circuits.
According to Dr. Francis Bellido, CEO of Quantum eMotion, the integration of QRNG-generated entropy demonstrates strong resistance to quantum attacks. This development supports the company’s security-by-design approach for Sentry-Q and aligns with its broader post-quantum product roadmap.
Looking forward, Quantum eMotion plans to develop hybrid testbenches and real-time emulation of cryptographic architectures with QRNG under constrained computing conditions. These advancements are expected to further validate the security features of the Sentry-Q architecture in embedded and edge environments.
For additional information, visit Quantum eMotion's website.
