We consider hyperspectral phase/amplitude imaging from hyperspectral complex-valued noisy observations. Block-matching and grouping of similar patches are main instruments of the proposed algorithms. The search neighborhood for similar patches spans both the spectral and 2D spatial dimensions. SVD analysis of 3D grouped patches is used for design of adaptive nonlocal bases. Simulation experiments demonstrate high efficiency of developed state-of-the-art algorithms.
Road traffic signs provide vital information about the traffic rules, road conditions, and route directions to assist drivers in safe driving. Recognition of traffic signs is one of the key features of Advanced Driver Assistance Systems (ADAS). In this paper, we present a Convolutional Neural Network (CNN) based approach for robust Traffic Sign Recognition (TSR) that can run real-time on low power embedded systems. To achieve this, we propose a twostage network: In the first stage, a generic traffic sign detection network localizes the position of traffic signs in the video footage, and in the second stage a country-specific classification network classifies the detected signs. The network sub-blocks were retrained to generate an optimal network that runs real-time on the Nvidia Tegra platform. The network?s computational complexity and the model size are further reduced to make it deployable on low power embedded platforms. Methods like network customization, weight pruning, and quantization schemes were used to achieve an 8X reduction in computation complexity. The pruned and optimized network is further ported and benchmarked on embedded platforms like Texas Instruments Jacinto TDA2x SoC and Qualcomm?s Snapdragon 820Automotive platform.