MUMBAI, India, Jan. 2 -- Intellectual Property India has published a patent application (202541123351 A) filed by Anurag Engineering College, Suryapet, Telangana, on Dec. 7, 2025, for 'metamaterial-based ultra-thin antenna arrays for high-capacity electromagnetic spectrum sharing.'
Inventor(s) include Mr Banavathu Naga Raju; and Mr Rama Krishna Karlapudi.
The application for the patent was published on Jan. 2, under issue no. 01/2026.
According to the abstract released by the Intellectual Property India: "The invention discloses an ultra-thin metamaterial-based antenna array engineered for advanced, high-capacity electromagnetic spectrum sharing in real time. Utilizing a reconfigurable metasurface architecture, the system provides dynamic beamforming, wideband frequency adaptability, and intelligent interference mitigation. AI-driven spectrum analytics continuously monitor and predict congestion, interference, and suboptimal channel utilization, enabling proactive reconfiguration of antenna parameters to maximize spectral efficiency. The lightweight and compact design reduces physical infrastructure requirements while maintaining high performance across diverse communication platforms. This multi-functional antenna array supports simultaneous operation for terrestrial networks, satellite communication, Internet of Things (IoT) ecosystems, and mission-critical defense systems. By integrating adaptive signal processing with predictive AI control, the system ensures robust connectivity, low latency, and improved reliability even in congested or contested spectral environments. Additionally, the architecture facilitates seamless integration with existing wireless infrastructure, promoting scalability and energy-efficient operation. The invention offers a transformative approach for next-generation wireless networks, combining compact form factor, intelligent spectrum management, and versatile deployment capabilities, thereby addressing the growing demand for reliable, high-throughput, and interference-resilient communication across heterogeneous platforms and dynamic operating conditions."
Disclaimer: Curated by HT Syndication.
