Abstract
Field-Programmable Gate Arrays (FPGAs) have emerged as a transformative technology in digital signal processing (DSP), offering unmatched flexibility, high performance, and real-time capabilities. This study explores the architecture of FPGAs, their integration with other digital systems, and the optimization methodologies that enhance their efficiency in diverse applications. From telecommunications and multimedia to biomedical and aerospace systems, FPGAs address the growing demand for adaptable, low-latency DSP solutions. The research highlights case studies, market trends, and future outlooks, demonstrating the pivotal role of FPGAs in shaping next-generation DSP technologies. By leveraging FPGA-specific features such as parallelism, pipelining, and dynamic reconfiguration, developers can meet the performance, efficiency, and scalability requirements of modern industries. The findings underscore the importance of continued innovation in FPGA-based DSP systems to drive advancements across emerging fields like AI, IoT, and autonomous systems. Keywords: FPGA, Digital Signal Processing (DSP), Real-Time Systems, Optimization Techniques, High- Performance Computing
Published Version
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