Skin Temperature Extraction Using Facial Landmark Detection and Thermal Imaging for Comfort Assessment

Despite the large share of energy consumption, current HVAC systems in buildings fail to meet their primary purpose of maintaining comfortable indoor conditions. Current "one size fits all" approach to control the thermal conditions in an environment lead to a high degree of occupant dissatisfaction. Advancements in Internet of Things and Machine Learning have opened the possibility of deploying different sensors at a wide scale to monitor environmental and physiological information and using collected sensor data to model individual comfort requirements. Thermal imaging has recently gained interest as one of the possible ways to monitor physiological information (skin temperature) for thermal comfort assessment. Previous studies have shown that skin temperatures from different regions of the face, such as forehead, nose, cheeks and ears can provide useful information for predicting thermal sensation at an individual level. However, existing approaches to process thermal images either rely on manual temperature extraction or use methods that are less reliable in accurately identifying different facial regions. One of the major challenges of using thermal imaging for monitoring skin temperatures in actual buildings is that occupants may move relative to the camera. It is not practical to expect building occupants to be oriented facing the cameras at all times, therefore, it is important to be able to extract as much information as possible from instances where it is feasible to extract relevant information. In this paper, we describe an approach to extract skin temperature by locating specific regions of the face in thermal images. The approach involves combining data from RGB images with thermal images and leveraging facial landmark detection in RGB images. We also evaluate our approach with existing approach of face detection used in previous studies. Our study demonstrates that facial landmark detection provides a more accurate calculation of different locations in the face compared to previous studies. We show an improvement in overall quantity and quality of temperature measurements extracted from thermal images compared to previous studies. More accurate temperature measurements from thermal images can improve the accuracy of thermal imaging for modeling and predicting thermal comfort.

[1]  P. O. Fanger,et al.  Thermal comfort: analysis and applications in environmental engineering, , 1972 .

[2]  Burcin Becerik-Gerber,et al.  Human-Building Interaction Framework for Personalized Thermal Comfort-Driven Systems in Office Buildings , 2014, J. Comput. Civ. Eng..

[3]  Burcin Becerik-Gerber,et al.  Smart Desks to Promote Comfort, Health, and Productivity in Offices: A Vision for Future Workplaces , 2019, Front. Built Environ..

[4]  Carol C. Menassa,et al.  Non-intrusive interpretation of human thermal comfort through analysis of facial infrared thermography , 2018, Energy and Buildings.

[5]  B. Becerik-Gerber,et al.  Energy consequences of Comfort-driven temperature setpoints in office buildings , 2018, Energy and Buildings.

[6]  Christoph van Treeck,et al.  Real-time human skin temperature analysis using thermal image recognition for thermal comfort assessment , 2018 .

[7]  Hui Zhang,et al.  Thermal sensation and comfort models for non-uniform and transient environments: Part III: whole-body sensation and comfort , 2009 .

[8]  Lihua Xie,et al.  Thermal comfort prediction using normalized skin temperature in a uniform built environment , 2018 .

[9]  Benjamin Johnston,et al.  A review of image-based automatic facial landmark identification techniques , 2018, EURASIP Journal on Image and Video Processing.

[10]  Josephine Sullivan,et al.  One millisecond face alignment with an ensemble of regression trees , 2014, 2014 IEEE Conference on Computer Vision and Pattern Recognition.

[11]  Renato Vidoni,et al.  Real-Time Monitoring of Occupants’ Thermal Comfort through Infrared Imaging: A Preliminary Study , 2017 .

[12]  Farrokh Jazizadeh,et al.  Vision-based thermal comfort quantification for HVAC control , 2018, Building and Environment.

[13]  Juhi Ranjan,et al.  ThermalSense: determining dynamic thermal comfort preferences using thermographic imaging , 2016, UbiComp.

[14]  Hui Zhang,et al.  The skin's role in human thermoregulation and comfort , 2006 .

[15]  Shichao Liu Personal thermal comfort models based on physiological parameters measured by wearable sensors , 2018 .

[16]  B. Becerik-Gerber,et al.  A comparative study of predicting individual thermal sensation and satisfaction using wrist-worn temperature sensor, thermal camera and ambient temperature sensor , 2019, Building and Environment.

[17]  Gail Brager,et al.  Analysis of the accuracy on PMV – PPD model using the ASHRAE Global Thermal Comfort Database II , 2019, Building and Environment.

[18]  Pramodita Sharma 2012 , 2013, Les 25 ans de l’OMC: Une rétrospective en photos.

[19]  H. Zhang,et al.  Human thermal sensation and comfort in transient and non-uniform thermal environments , 2003 .

[20]  Rahul Simha,et al.  Thermal comfort modeling in transient conditions using real-time local body temperature extraction with a thermographic camera , 2018, Building and Environment.

[21]  Zhiwei Lian,et al.  Thermal perception and skin temperature in different transient thermal environments in summer , 2016 .

[22]  Joyce Kim,et al.  Personal comfort models – A new paradigm in thermal comfort for occupant-centric environmental control , 2018 .

[23]  Changzhi Li,et al.  A Review on Recent Advances in Doppler Radar Sensors for Noncontact Healthcare Monitoring , 2013, IEEE Transactions on Microwave Theory and Techniques.

[24]  Mohamed Abouelenien,et al.  Multimodal Sensing of Thermal Discomfort for Adaptive Energy Saving in Buildings , 2014 .

[25]  Burcin Becerik-Gerber,et al.  Towards unsupervised learning of thermal comfort using infrared thermography , 2018 .

[26]  Nicolas Morel,et al.  A personalized measure of thermal comfort for building controls , 2011 .

[27]  Stefano Schiavon,et al.  Percentage of commercial buildings showing at least 80% occupant satisfied with their thermal comfort , 2018 .

[28]  Gail Brager,et al.  Developing an adaptive model of thermal comfort and preference , 1998 .

[29]  Dongwoo Yeom,et al.  Study of data-driven thermal sensation prediction model as a function of local body skin temperatures in a built environment , 2017 .

[30]  Carol C. Menassa,et al.  Robust non-intrusive interpretation of occupant thermal comfort in built environments with low-cost networked thermal cameras , 2019, Applied Energy.

[31]  Kwang Suk Park,et al.  Estimation of Thermal Sensation Based on Wrist Skin Temperatures , 2016, Sensors.

[32]  Ryozo Ooka,et al.  Thermal comfort, skin temperature distribution, and sensible heat loss distribution in the sitting posture in various asymmetric radiant fields , 2007 .

[33]  Paul A. Viola,et al.  Rapid object detection using a boosted cascade of simple features , 2001, Proceedings of the 2001 IEEE Computer Society Conference on Computer Vision and Pattern Recognition. CVPR 2001.