Green Automation Solutions for Energy-Efficient Electronics: Sustainable Design, Implementation, and Performance Strategies

Abstract

The industrial automation, consumer electronics and smart infrastructure are growing at a terrific pace which has heightened the trend towards energy consumption, carbon emissions and environmental sustainability around the world. In this paper, the author will provide a review of green approaches to automation that integrates sustainable engineering principles with leading edge control strategies to provide energy-efficient electronics. The aim will be to determine, analyze and combine the sustainable design approach, greener material use, power-efficient circuit design, and smart automation algorithms to cut energy use without the need to affect performance penalties. Methodologically, the review will cover recent scholarly studies, reports in the industry, and case studies of renewable-powered automation systems, low-power embedded devices, and smart manufacturing platform. The performance strategies are mapped between lifecycle energy efficiency, lower carbon footprint, and savings in operating cost. Findings show that intertwining renewable energy, energy management using AI, and establishing green manufacturing requirements have the potential to save 20-45 percent energy across different consumer and industrial products. Case studies prove quantifiable levels of efficiency gains as a result of implementing adaptive control algorithms and sustainable material selection. The paper comes to the conclusion that in the future, the advancement will necessitate interdisciplinary collegiality, common frameworks of green certification, and integrable renewable scalability to balance technological innovation with environmental conscious. The observation makes green automation an urgent channel through which future sustainable industrial and electronic systems can be advanced.