Phase Cascade Bridge Rectifier Array in a 2-D lattice

TL;DR

This paper introduces a novel phase cascade rectifier array in a 2-D lattice that achieves zero current ripple in the large N limit, improving rectification efficiency without external filters.

Contribution

It presents a new phase cascade configuration for 2-D diode networks that enhances rectification efficiency and differs from conventional rectenna arrays.

Findings

Current ripple approaches zero as N increases.

The phase cascade configuration outperforms traditional rectifiers.

Analytical results match realistic diode simulations.

Abstract

We report on a novel rectification phenomenon in a 2-D lattice network consisting of $N\times N$ sites with diode and AC source elements with controllable phases. A phase cascade configuration is described in which the current ripple in a load resistor goes to zero in the large $N$ limit, enhancing the rectification efficiency without requiring any external capacitor or inductor based filters. The integrated modular configuration is qualitatively different from conventional rectenna arrays in which the source, rectifier and filter systems are physically disjoint. Exact analytical results derived using idealized diodes are compared to a realistic simulation of commercially available diodes. Our results on nonlinear networks of source-rectifier arrays are potentially of interest to a fast evolving field of distributed power networks.