The Army Rapid Capabilities Office (RCO) is gearing up to launch a challenge seeking artificial intelligence and machine learning algorithms for better radio frequency analysis. Specifically, the Army wants algorithms for "blind signal identification and classification" -- identification of signals without any prior knowledge of the signals present in a radio frequency channel. "Army soldiers are responsible for understanding a vast amount of information presented to them," a FedBizOpps announcement of the challenge reads. "Compounding the issue is the source and location information of, potentially, an infinite number of electronic signals through various sensing means, coordinating defensive and offensive operations to defend against electronic attack, and blunt the electronic means of the threat." Artificial intelligence, RCO hopes, can help.

The complex wave representation (CWR) converts unsigned 2D distance transforms into their corresponding wave functions. Here, the distance transform S(X) appears as the phase of the wave function \phi(X)---specifically, \phi(X)=exp(iS(X)/\tau where \tau is a free parameter. In this work, we prove a novel result using the higher-order stationary phase approximation: we show convergence of the normalized power spectrum (squared magnitude of the Fourier transform) of the wave function to the density function of the distance transform gradients as the free parameter \tau-->0. In colloquial terms, spatial frequencies are gradient histogram bins. Since the distance transform gradients have only orientation information (as their magnitudes are identically equal to one almost everywhere), as \tau-->0, the 2D Fourier transform values mainly lie on the unit circle in the spatial frequency domain. The proof of the result involves standard integration techniques and requires proper ordering of limits. Our mathematical relation indicates that the CWR of distance transforms is an intriguing, new representation.

This paper presents a coordination algorithm for mobile autonomous robots. Relying upon distributed sensing the robots achieve rendezvous, that is, they move to a common location. Each robot is a point mass moving in a nonconvex environment according to an omnidirectional kinematic model. Each robot is equipped with line-of-sight limited-range sensors, i.e., a robot can measure the relative position of any object (robots or environment boundary) if and only if the object is within a given distance and there are no obstacles in-between. The algorithm is designed using the notions of robust visibility, connectivity-preserving constraint sets, and proximity graphs. Simulations illustrate the theoretical results on the correctness of the proposed algorithm, and its performance in asynchronous setups and with sensor measurement and control errors.