Towards unsupervised learning of thermal comfort using infrared thermography

Maintaining thermal comfort in built environments is important for occupant health, well-being, and productivity, and also for efficient HVAC system operations. Most of the existing personal thermal comfort learning methods require occupants to provide feedback via a survey to label the monitored environmental or physiological conditions in order to train the prediction models. Accuracy of these models usually drops after the training process as personal thermal comfort is dynamic and changes over time due to climatic variations and/or acclimation. In this paper, we present a hidden Markov model (HMM) based learning method to capture personal thermal comfort using infrared thermography of the human face. We chose human face since its blood vessels has a higher density and it is not covered while performing regular activities in built environments. The learning algorithm has 3 hidden states (i.e., uncomfortably warm, comfortable, uncomfortably cool) and uses discretization for forming the observed states from the continuous infrared measurements. The approach can potentially be used for continuous monitoring of thermal comfort to capture the variations over time. We tested and validated the method in a four-day long experiment with 10 subjects and demonstrated an accuracy of 82.8% for predicting uncomfortable conditions.

[1]  W D van Marken Lichtenbelt,et al.  Differences between young adults and elderly in thermal comfort, productivity, and thermal physiology in response to a moderate temperature drift and a steady-state condition. , 2010, Indoor air.

[2]  Andrew J. Viterbi,et al.  Error bounds for convolutional codes and an asymptotically optimum decoding algorithm , 1967, IEEE Trans. Inf. Theory.

[3]  Philomena M. Bluyssen,et al.  Towards new methods and ways to create healthy and comfortable buildings , 2010 .

[4]  Burcin Becerik-Gerber,et al.  Energy savings from temperature setpoints and deadband: Quantifying the influence of building and system properties on savings , 2016 .

[5]  Richard de Dear,et al.  Adaptation and Thermal Environment , 2009 .

[6]  Burcin Becerik-Gerber,et al.  An online learning approach for quantifying personalized thermal comfort via adaptive stochastic modeling , 2015 .

[7]  Burcin Becerik-Gerber,et al.  A framework for allocating personalized appliance-level disaggregated electricity consumption to daily activities , 2016 .

[8]  Burcin Becerik-Gerber,et al.  A knowledge based approach for selecting energy-aware and comfort-driven HVAC temperature set points , 2014 .

[9]  Burcin Becerik-Gerber,et al.  HVAC system energy optimization using an adaptive hybrid metaheuristic , 2017 .

[10]  Jerrold Scott Petrofsky,et al.  Resting Blood Flow in the Skin: Does it Exist, and What is the Influence of Temperature, Aging, and Diabetes? , 2012, Journal of diabetes science and technology.

[11]  John E. Taylor,et al.  Energy Saving Alignment Strategy: Achieving energy efficiency in urban buildings by matching occupant temperature preferences with a building’s indoor thermal environment , 2014 .

[12]  B W Olesen,et al.  International standards for the indoor environment. , 2004, Indoor air.

[13]  Xue Feng,et al.  Breathable and Stretchable Temperature Sensors Inspired by Skin , 2015, Scientific Reports.

[14]  S. A. Al-Sanea,et al.  Optimized monthly-fixed thermostat-setting scheme for maximum energy-savings and thermal comfort in air-conditioned spaces , 2008 .

[15]  S. Matsumoto,et al.  Prediction of whole-body thermal sensation in the non-steady state based on skin temperature , 2013 .

[16]  Somayeh Asadi,et al.  Development of a new methodology to optimize building life cycle cost, environmental impacts, and occupant satisfaction , 2017 .

[17]  David Lehrer,et al.  Listening to the occupants: a Web-based indoor environmental quality survey. , 2004, Indoor air.

[18]  Bjarne W. Olesen,et al.  A relation between calculated human body exergy consumption rate and subjectively assessed thermal sensation , 2011 .

[19]  Anastasios I. Dounis,et al.  Design of a fuzzy system for living space thermal-comfort regulation , 2001 .

[20]  van J Joost Hoof,et al.  Forty years of Fanger’s model of thermal comfort: comfort for all? , 2008 .

[21]  R. Dear,et al.  Thermal adaptation in the built environment: a literature review , 1998 .

[22]  Charlie Huizenga,et al.  Skin and core temperature response to partial- and whole-body heating and cooling , 2004 .

[23]  Eiji Kobayashi,et al.  Hypothermic temperature effects on organ survival and restoration , 2015, Scientific Reports.

[24]  Mohammad. Rasul,et al.  Thermal-comfort analysis and simulation for various low-energy cooling-technologies applied to an office building in a subtropical climate , 2008 .

[25]  Zhaojun Wang,et al.  Thermal history and adaptation: Does a long-term indoor thermal exposure impact human thermal adaptability? , 2016 .

[26]  Charles Culp,et al.  The effect of temperature, metabolic rate and dynamic localized airflow on thermal comfort , 2013 .

[27]  Joris C Verster,et al.  The effect of stress on core and peripheral body temperature in humans , 2013, Stress.

[28]  Weiwei Liu,et al.  A neural network evaluation model for individual thermal comfort , 2007 .

[29]  S. Sekhar,et al.  Thermal comfort in air-conditioned buildings in hot and humid climates--why are we not getting it right? , 2016, Indoor air.

[30]  Javier Tarrío-Saavedra,et al.  Assessing thermal comfort and energy efficiency in buildings by statistical quality control for autocorrelated data , 2017 .

[31]  Burcin Becerik-Gerber,et al.  A Study of Time-Dependent Variations in Personal Thermal Comfort via a Dynamic Bayesian Network , 2015 .

[32]  T. McMahon,et al.  Updated world map of the Köppen-Geiger climate classification , 2007 .

[33]  Yi Jiang,et al.  A data-driven method to describe the personalized dynamic thermal comfort in ordinary office environment: From model to application , 2014 .

[34]  S. Karjalainen,et al.  Thermal comfort and gender: a literature review. , 2012, Indoor air.

[35]  Panajotis Agathoklis,et al.  A new thermostat for real-time price demand response: Cost, comfort and energy impacts of discrete-time control without deadband , 2015 .

[36]  Nisha Charkoudian,et al.  Skin blood flow in adult human thermoregulation: how it works, when it does not, and why. , 2003, Mayo Clinic proceedings.

[37]  Brm Boris Kingma,et al.  Thermal sensation: a mathematical model based on neurophysiology. , 2012, Indoor air.

[38]  Mahmoud Alahmad,et al.  A Review of Approaches for Sensing, Understanding, and Improving Occupancy-Related Energy-Use Behaviors in Commercial Buildings , 2015 .

[39]  R. Yao,et al.  A theoretical adaptive model of thermal comfort – Adaptive Predicted Mean Vote (aPMV) , 2009 .

[40]  Kodo Kawase,et al.  Morphology of human sweat ducts observed by optical coherence tomography and their frequency of resonance in the terahertz frequency region , 2015, Scientific Reports.

[41]  Mahmoud Alahmad,et al.  Development of Non-Intrusive Occupant Load Monitoring (NIOLM) in Commercial Buildings: Assessing Occupants’ Energy-Use Behavior at Entry and Departure Events , 2015 .

[42]  Standard Ashrae Thermal Environmental Conditions for Human Occupancy , 1992 .

[43]  Y Yao,et al.  Heart rate variation and electroencephalograph--the potential physiological factors for thermal comfort study. , 2009, Indoor air.

[44]  I D Swain,et al.  Methods of measuring skin blood flow. , 1989, Physics in medicine and biology.

[45]  Changbum R. Ahn,et al.  Linking Building Energy-Load Variations with Occupants’ Energy-Use Behaviors in Commercial Buildings: Non-Intrusive Occupant Load Monitoring (NIOLM) , 2016 .

[46]  Burcin Becerik-Gerber,et al.  One size does not fit all: Understanding user preferences for building automation systems , 2017 .

[47]  Burcin Becerik-Gerber,et al.  Infrared thermography of human face for monitoring thermoregulation performance and estimating personal thermal comfort , 2016 .

[48]  Kevin P. Murphy,et al.  Machine learning - a probabilistic perspective , 2012, Adaptive computation and machine learning series.

[49]  Luis de la Ossa,et al.  Design and simulation of a thermal comfort adaptive system based on fuzzy logic and on-line learning , 2012 .