Fatigability, Exercise Intolerance, and Abnormal Skeletal Muscle Energetics in Heart Failure

Neural networks are becoming central in several areas of computer vision and image processing and different architectures have been proposed to solve specific problems. The impact of the loss layer of neural networks, however, has not received much attention in the context of image processing: the default and virtually only choice is 2. In this paper, we bring attention to alternative choices for image restoration. In particular, we show the importance of perceptually-motivated losses when the resulting image is to be evaluated by a human observer. We compare the performance of several losses, and propose a novel, differentiable error function. We show that the quality of the results improves significantly with better loss functions, even when the network architecture is left unchanged.

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Importance Estimation for Neural Network Pruning

Molchanov

et al. 2019

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Structural pruning of neural network parameters reduces computation, energy, and memory transfer costs during inference. We propose a novel method that estimates the contribution of a neuron (filter) to the final loss and iteratively removes those with smaller scores. We describe two variations of our method using the first and secondorder Taylor expansions to approximate a filter's contribution. Both methods scale consistently across any network layer without requiring per-layer sensitivity analysis and can be applied to any kind of layer, including skip connections. For modern networks trained on ImageNet, we measured experimentally a high (>93%) correlation between the contribution computed by our methods and a reliable estimate of the true importance. Pruning with the proposed methods leads to an improvement over state-ofthe-art in terms of accuracy, FLOPs, and parameter reduction. On ResNet-101, we achieve a 40% FLOPS reduction by removing 30% of the parameters, with a loss of 0.02% in the top-1 accuracy on ImageNet. Code is available at https://github.com/NVlabs/Taylor_pruning.

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Autocalibration of MEMS Accelerometers

Frosio

Pedersini

Borghese

2009

IEEE Trans. Instrum. Meas.

158

104

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Robust Model-Based 3D Head Pose Estimation

Meyer

Gupta²,

Frosio³

et al. 2015

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3D analysis of the body center of mass in rock climbing

Sibella

Frosio

Schena

et al. 2007

Human Movement Science

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Loss Functions for Neural Networks for Image Processing

Zhao¹,

Gallo²,

Frosio³

et al. 2015

Preprint

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Tackling 3D ToF Artifacts Through Learning and the FLAT Dataset

Guo

Frosio

Gallo

et al. 2018

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Scene motion, multiple reflections, and sensor noise introduce artifacts in the depth reconstruction performed by time-of-flight cameras. We propose a two-stage, deep-learning approach to address all of these sources of artifacts simultaneously. We also introduce FLAT, a synthetic dataset of 2000 ToF measurements that capture all of these nonidealities, and allows to simulate different camera hardware. Using the Kinect 2 camera as a baseline, we show improved reconstruction errors over state-of-the-art methods, on both simulated and real data.

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Autocalibration of Triaxial MEMS Accelerometers With Automatic Sensor Model Selection

2012

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Iuri Frosio

Loss Functions for Image Restoration With Neural Networks

Importance Estimation for Neural Network Pruning

Autocalibration of MEMS Accelerometers

Robust Model-Based 3D Head Pose Estimation

3D analysis of the body center of mass in rock climbing

Loss Functions for Neural Networks for Image Processing

Tackling 3D ToF Artifacts Through Learning and the FLAT Dataset

Autocalibration of Triaxial MEMS Accelerometers With Automatic Sensor Model Selection

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