This paper presents a 1-bit reconfigurable intelligent surface (RIS) fabricated using a three-layer structure. It employs a manual layer stackup incorporating an optimal air gap to reduce the effective dielectric losses while using a low-cost FR4 substrate. The new design of the unit cells of the proposed RIS is outlined, with each unit cell featuring a PIN-diode-based, compact, simplified biasing network that simplifies the control circuit while maintaining distinct 0∘/180∘±20∘ phase states between ON/OFF conditions. The designed RIS is in the form of a 10×10 array with a compact size of 2.9λg×2.9λg. Additionally, a phase-gradient coding scheme is presented and utilized that achieves measured beam steering up to ±30∘ in both anechoic and noisy environments. Controlled and driven by an Arduino-cum-digital interface, the proposed RIS exhibits measured reflected wave gain enhancement of about 9\,dB over an incident wave angular range of ±30∘. Furthermore, the design is also experimentally validated by transmitting quadrature phase-shift keying-modulated symbols via the RIS-assisted wireless channel. The proposed RIS works for the range 3.38--3.67\,GHz (8.3\%), and is suitable for deployment for the 5G n78 \mbox{band (3.5\,GHz).}
@article{arxiv.2604.04625,
title = {Compact Reconfigurable Intelligent Surface with Phase-Gradient Coded Beam Steering and Controlled Substrate Loss},
author = {Mahendra Kheti and Debapratim Ghosh and Soumya P. Dash},
journal= {arXiv preprint arXiv:2604.04625},
year = {2026}
}