Design and Simulation of Hybrid Analog-Digital Circuit Architectures for High-Speed Signal Processing Systems

Abstract

High-speed signal processing systems are at the core of numerous applications such as telecommunications, radar systems, and high-frequency trading. These systems require efficient architectures capable of processing large amounts of data in real-time. Traditional analog circuits offer high-speed processing with low latency, but they suffer from limitations such as noise susceptibility and scalability. On the other hand, digital circuits provide precision, scalability, and flexibility but at the expense of speed. This paper presents the design and simulation of hybrid analog-digital circuit architectures that combine the benefits of both domains. The proposed hybrid architecture leverages the speed of analog circuits and the accuracy of digital circuits to improve the overall performance of high-speed signal processing systems. Through simulation results and comparison with traditional architectures, the paper demonstrates the effectiveness of this approach in terms of speed, efficiency, and noise immunity.