Physics-Inspired Discrete-Phase Optimization for 3D Beamforming with PIN-Diode Extra-Large Antenna Arrays
CoRR(2023)
摘要
Large antenna arrays can steer narrow beams towards a target area, and thus
improve the communications capacity of wireless channels and the fidelity of
radio sensing. Hardware that is capable of continuously-variable phase shifts
is expensive, presenting scaling challenges. PIN diodes that apply only
discrete phase shifts are promising and cost-effective; however, unlike
continuous phase shifters, finding the best phase configuration across elements
is an NP-hard optimization problem. Thus, the complexity of optimization
becomes a new bottleneck for large-antenna arrays. To address this challenge,
this paper suggests a procedure for converting the optimization objective
function from a ratio of quadratic functions to a sequence of more easily
solvable quadratic unconstrained binary optimization (QUBO) sub-problems. This
conversion is an exact equivalence, and the resulting QUBO forms are standard
input formats for various physics-inspired optimization methods. We demonstrate
that a simulated annealing approach is very effective for solving these
sub-problems, and we give performance metrics for several large array types
optimized by this technique. Through numerical experiments, we report 3D
beamforming performance for extra-large arrays with up to 10,000 elements.
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