Abstract

The rapid evolution of industrial automation has increased the demand for reliable wireless communication and embedded control integration. Conventional System-on-Chip architectures have lacked the capability to jointly optimize microwave behavior and embedded processing, which has resulted in performance degradation under industrial interference conditions. This study has addressed the challenge by proposing a Microwave-Aware Circuit-Embedded Co-Design (MACE-CoD) method, that has integrated RF circuit characteristics with digital control subsystems at the design stage. The proposed method has considered the electromagnetic interactions, that which has influenced signal integrity, latency, and power consumption across multi-domain components. A co-simulation framework has been developed, which has combined microwave circuit modeling with embedded firmware optimization. The architecture has enabled adaptive tuning mechanisms, that which has responded to environmental variations in real time. Experimental results show that the proposed MACE-CoD method achieves an SNR of 26 dB, that which improves performance by 44%, reduces latency to 5 ms, that which decreases delay by 37%, and lowers energy consumption to 42 mW, that which enhances efficiency by 30%. The system attains a packet delivery ratio of 98% and reduces the bit error rate to 0.01, that which ensures high reliability under industrial interference conditions.

Authors

Raja Ram Sah, Sudhir Kumar
Government Engineering College Jehanabad, India

Keywords

System-on-Chip, Microwave Co-Design, Industrial Wireless Communication, Embedded Control, Reliability Optimization