New orbital angular momentum multiplexing strategy: beyond the capacity limit of free-space optical communication

TL;DR

This paper introduces a novel IRD-OAM multiplexing strategy that significantly surpasses traditional OAM capacity limits in free-space optical communication, enabling higher capacity, longer distances, and smaller receiver sizes without extra hardware.

Contribution

The paper proposes and experimentally demonstrates a new IRD-OAM multiplexing method that overcomes the physical limits of conventional OAM multiplexing in FSO links.

Findings

Achieves up to 1238% capacity of conventional OAM multiplexing.

Enables 403% longer communication distance compared to traditional methods.

Allows for receiver sizes 26.9% smaller while maintaining capacity.

Abstract

Free space optical (FSO) communication can exploit mode-division multiplexing using orthogonal spatial modes of Laguerre Gaussian beams, such as orbital angular momentum (OAM) modes, wherein OAM multiplexing offers potentially infinite information capacity due to the arbitrary quantization of OAM. Combined with polarization-division multiplexing and wavelength-division multiplexing, OAM multiplexing is a promising solution for future capacity demands. However, the practically addressable number of spatial subchannels is severely limited by the receiver size and the rapid beam expansion with increasing mode order and communication distance. Based on the intrinsic and distinctive property that the divergent degree of the innermost ring of a Laguerre-Gaussian beam is significantly slower than that of the beam cross-section during propagation, here we propose theoretically and demonstrate experimentally a novel communication strategy innermost ring dominated OAM (IRD-OAM) multiplexingn that can overcome these limits and achieve up to 1238% capacity of conventional OAM multiplexing in a canonical FSO link system without any additional hardware modifications. Alternatively, our strategy can also enable longer communication distance (403% of that for conventional OAM multiplexing), or smaller receiver (26.9% in size compared to conventional OAM multiplexing), while maintaining the same capacity as conventional OAM multiplexing. Our work will hasten the development of future FSO communications with ultra high capacity, ultra long distance and highly-integrated devices for deep space, near Earth and Earth surface applications.