LumNet: Learning to Estimate Vertical Visual Field Luminance for Adaptive Lighting Control

High-quality lighting positively influences visual performance in humans. The experienced visual performance can be measured using desktop luminance and hence several lighting control systems have been developed for its quantification. However, the measurement devices that are used to monitor the desktop luminance in existing lighting control systems are obtrusive to the users. As an alternative, ceiling-based luminance projection sensors are being used recently as these are unobtrusive and can capture the direct task area of a user. The positioning of these devices on the ceiling requires to estimate the desktop luminance in the user’s vertical visual field, solely using ceiling-based measurements, to better predict the experienced visual performance of the user. For this purpose, we present LumNet, an approach for estimating desktop luminance with deep models through utilizing supervised and self-supervised learning. Our model learns visual representations from ceiling-based images, which are collected in indoor spaces within the physical vicinity of the user to predict average desktop luminance as experienced in a real-life setting. We also propose a self-supervised contrastive method for pre-training LumNet with unlabeled data and we demonstrate that the learned features are transferable onto a small labeled dataset which minimizes the requirement of costly data annotations. Likewise, we perform experiments on domain-specific datasets and show that our approach significantly improves over the baseline results from prior methods in estimating luminance, particularly in the low-data regime. LumNet is an important step towards learning-based technique for luminance estimation and can be used for adaptive lighting control directly on-device thanks to its minimal computational footprint with an added benefit of preserving user’s privacy.

[1]  Alexander Kolesnikov,et al.  Revisiting Self-Supervised Visual Representation Learning , 2019, 2019 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR).

[2]  Mark S. Rea,et al.  Relative visual performance: A basis for application , 1991 .

[3]  Ali Motamed,et al.  VALIDATION AND PRELIMINARY EXPERIMENTS OF EMBEDDED DISCOMFORT GLARE ASSESSMENT THROUGH A NOVEL HDR VISION SENSOR , 2015 .

[4]  Jitendra Malik,et al.  SlowFast Networks for Video Recognition , 2018, 2019 IEEE/CVF International Conference on Computer Vision (ICCV).

[5]  Lawrence D. Jackel,et al.  Backpropagation Applied to Handwritten Zip Code Recognition , 1989, Neural Computation.

[6]  Ziad Boulos,et al.  Light treatment for sleep disorders: Consensus report .7. Jet lag , 1995 .

[7]  Anil A. Bharath,et al.  On denoising autoencoders trained to minimise binary cross-entropy , 2017, ArXiv.

[8]  J. Lönnqvist,et al.  Bright light improves vitality and alleviates distress in healthy people. , 2000, Journal of affective disorders.

[9]  Sanja Fidler,et al.  Skip-Thought Vectors , 2015, NIPS.

[10]  Quoc V. Le,et al.  AutoAugment: Learning Augmentation Policies from Data , 2018, ArXiv.

[11]  Ali Motamed,et al.  On-site monitoring and subjective comfort assessment of a sun shadings and electric lighting controller based on novel High Dynamic Range vision sensors , 2017 .

[12]  Tao Fang On performance of lossless compression for HDR image quantized in color space , 2009, Signal Process. Image Commun..

[13]  Wjm van Bommel,et al.  Lighting for work: a review of visual and biological effects , 2004 .

[14]  Geoffrey E. Hinton,et al.  ImageNet classification with deep convolutional neural networks , 2012, Commun. ACM.

[15]  C Cuttle,et al.  Brightness, lightness, and providing ‘a preconceived appearance to the interior’ , 2004 .

[16]  Li Bai,et al.  Cosine Similarity Metric Learning for Face Verification , 2010, ACCV.

[17]  Sergey Levine,et al.  Time-Contrastive Networks: Self-Supervised Learning from Video , 2017, 2018 IEEE International Conference on Robotics and Automation (ICRA).

[18]  K. K. Sahu,et al.  Normalization: A Preprocessing Stage , 2015, ArXiv.

[19]  Kaiming He,et al.  Faster R-CNN: Towards Real-Time Object Detection with Region Proposal Networks , 2015, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[20]  Max Welling,et al.  Auto-Encoding Variational Bayes , 2013, ICLR.

[21]  Beat Gfeller,et al.  Sense and Learn: Self-Supervision for Omnipresent Sensors , 2020, Machine Learning with Applications.

[22]  Alexander Rosemann,et al.  The bee-eye: a practical device for measuring the luminance distribution , 2017 .

[23]  Li Fei-Fei,et al.  ImageNet: A large-scale hierarchical image database , 2009, CVPR.

[24]  Walker Hk,et al.  Visual Fields -- Clinical Methods: The History, Physical, and Laboratory Examinations , 1990 .

[25]  Jennifer A. Veitch,et al.  Preferred luminous conditions in open-plan offices: research and practice recommendations , 2000 .

[26]  Alexei A. Efros,et al.  Colorful Image Colorization , 2016, ECCV.

[27]  Mehlika Inanici,et al.  A Critical Investigation of Common Lighting Design Metrics for Predicting Human Visual Comfort in Offices with Daylight , 2014 .

[28]  David R. Musicant,et al.  Robust Linear and Support Vector Regression , 2000, IEEE Trans. Pattern Anal. Mach. Intell..

[29]  Shane Legg,et al.  Human-level control through deep reinforcement learning , 2015, Nature.

[30]  Alexei A. Efros,et al.  Split-Brain Autoencoders: Unsupervised Learning by Cross-Channel Prediction , 2016, 2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[31]  Pieter Abbeel,et al.  CURL: Contrastive Unsupervised Representations for Reinforcement Learning , 2020, ICML.

[32]  E. J. van Loenen,et al.  Feasibility of ceiling-based luminance distribution measurements , 2020 .

[33]  Dj Carter,et al.  A field study of occupant controlled lighting in offices , 2002 .

[34]  Nitish Srivastava Unsupervised Learning of Visual Representations using Videos , 2015 .

[35]  Andrew Y. Ng,et al.  CheXNet: Radiologist-Level Pneumonia Detection on Chest X-Rays with Deep Learning , 2017, ArXiv.

[36]  Dahua Lin,et al.  Unsupervised Feature Learning via Non-Parametric Instance-level Discrimination , 2018, ArXiv.

[37]  Ming-Wei Chang,et al.  BERT: Pre-training of Deep Bidirectional Transformers for Language Understanding , 2019, NAACL.

[38]  Ronald M. Summers,et al.  ChestX-ray: Hospital-Scale Chest X-ray Database and Benchmarks on Weakly Supervised Classification and Localization of Common Thorax Diseases , 2019, Deep Learning and Convolutional Neural Networks for Medical Imaging and Clinical Informatics.

[39]  Peter Boyce,et al.  Lighting appraisal, well-being and performance in open-plan offices: A linked mechanisms approach , 2008 .

[40]  T. W. Kruisselbrink Practical and continuous luminance distribution measurements for lighting quality , 2020 .

[41]  Mehlika Inanici,et al.  Evaluation of high dynamic range photography as a luminance data acquisition system , 2006 .

[42]  Peter Boyce,et al.  Occupant use of switching and dimming controls in offices , 2006 .

[43]  Subhashini Venugopalan,et al.  Development and Validation of a Deep Learning Algorithm for Detection of Diabetic Retinopathy in Retinal Fundus Photographs. , 2016, JAMA.

[44]  Andrew Zisserman,et al.  Very Deep Convolutional Networks for Large-Scale Image Recognition , 2014, ICLR.

[45]  Yi Li,et al.  Fully Convolutional Instance-Aware Semantic Segmentation , 2016, 2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[46]  Matthijs Douze,et al.  Deep Clustering for Unsupervised Learning of Visual Features , 2018, ECCV.

[47]  R Devon Hjelm,et al.  Learning Representations by Maximizing Mutual Information Across Views , 2019, NeurIPS.

[48]  Soumith Chintala,et al.  Unsupervised Representation Learning with Deep Convolutional Generative Adversarial Networks , 2015, ICLR.

[49]  R. Küller,et al.  Melatonin, cortisol, EEG, ECG and subjective comfort in healthy humans: Impact of two fluorescent lamp types at two light intensities , 1993 .

[50]  Stefan Carlsson,et al.  CNN Features Off-the-Shelf: An Astounding Baseline for Recognition , 2014, 2014 IEEE Conference on Computer Vision and Pattern Recognition Workshops.

[51]  Nikos Komodakis,et al.  Unsupervised Representation Learning by Predicting Image Rotations , 2018, ICLR.

[52]  Oriol Vinyals,et al.  Representation Learning with Contrastive Predictive Coding , 2018, ArXiv.

[53]  Xiang Zhang,et al.  OverFeat: Integrated Recognition, Localization and Detection using Convolutional Networks , 2013, ICLR.

[54]  Geoffrey E. Hinton,et al.  A Simple Framework for Contrastive Learning of Visual Representations , 2020, ICML.

[55]  Richard Socher,et al.  Knowing When to Look: Adaptive Attention via a Visual Sentinel for Image Captioning , 2016, 2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[56]  Kaiming He,et al.  Momentum Contrast for Unsupervised Visual Representation Learning , 2019, 2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR).

[57]  Evert van Loenen,et al.  Ceiling-based luminance measurements: a feasible solution? , 2019 .

[58]  P. Boyce,et al.  Age, illuminance, visual performance and preference , 1973 .

[59]  Alexei A. Efros,et al.  Contrastive Learning for Unpaired Image-to-Image Translation , 2020, ECCV.

[60]  Chao Yang,et al.  A Survey on Deep Transfer Learning , 2018, ICANN.

[61]  Samy Bengio,et al.  Show and tell: A neural image caption generator , 2014, 2015 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[62]  Jimmy Ba,et al.  Adam: A Method for Stochastic Optimization , 2014, ICLR.