Design Strategies For High-Efficiency Reversible Decoders In Fault-Tolerant Applications
Keywords:
Reversible Decoder, High speed, MOS Transistor, low powerAbstract
This research presents an innovative design methodology for developing generalized n-to-2ⁿ decoder
circuits using reversible logic principles. The proposed architecture relies exclusively on inherently fault
tolerant reversible gates — primarily the Fredkin gate and the Feynman double gate — which enable built
in error detection and correction capabilities across all levels of the circuit hierarchy. The study introduces
a systematic, scalable algorithmic approach for constructing these decoders for any number of input lines
(n). Additionally, it establishes theoretical lower bounds for essential performance parameters such as the
number of constant inputs, garbage outputs, and quantum cost. These metrics serve as critical benchmarks
for assessing the efficiency of fault-tolerant reversible decoder designs. Extensive comparative evaluations
demonstrate that the proposed architecture significantly outperforms existing designs in terms of quantum
cost, propagation delay, hardware complexity, and overall scalability. The results highlight the potential of
reversible logic in building efficient, reliable, and future-ready digital systems.











