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FeverPhone: Accessible Core-Body Temperature Sensing for Fever Monitoring Using Commodity Smartphones

Authors:

Mastafa Springston,

Alex Mariakakis,

Shwetak PatelAuthors Info & Claims

Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies, Volume 7, Issue 1

Article No.: 3, Pages 1 - 23

https://doi.org/10.1145/3580850

Published: 28 March 2023 Publication History

Abstract

Smartphones contain thermistors that ordinarily monitor the temperature of the device's internal components; however, these sensors are also sensitive to warm entities in contact with the device, presenting opportunities for measuring human body temperature and detecting fevers. We present FeverPhone --- a smartphone app that estimates a person's core body temperature by having the user place the capacitive touchscreen of the phone against their forehead. During the assessment, the phone logs the temperature sensed by a thermistor and the raw capacitance sensed by the touchscreen to capture features describing the rate of heat transfer from the body to the device. These features are then used in a machine learning model to infer the user's core body temperature. We validate FeverPhone through both a lab simulation with a skin-like controllable heat source and a clinical study with real patients. We found that FeverPhone's temperature estimates are comparable to commercial off-the-shelf peripheral and tympanic thermometers. In a clinical study with 37 participants, FeverPhone readings achieved a mean absolute error of 0.229 °C, a limit of agreement of ±0.731 °C, and a Pearson's correlation coefficient of 0.763. Using these results for fever classification results in a sensitivity of 0.813 and a specificity of 0.904.

References

[1]

[n. d.]. Fever. https://www.cedars-sinai.org/health-library/diseases-and-conditions/f/fever.html. Accessed: 2022-06-30.

[2]

[n. d.]. Huawei's clever new smartphone can take your temperature. https://www.fastcompany.com/90513189/huaweis-new-smartphone-can-take-your-temperature. Accessed: 2021-02-18.

[3]

[n. d.]. Temperature: Digital and Glass Thermometers. https://www.nationwidechildrens.org/family-resources-education/health-wellness-and-safety-resources/helping-hands/temperature-digital-and-glass-thermometers. Accessed: 2022-08-15.

[4]

[n. d.]. Temperature Measurement for Patients with Fever. https://www.uspharmacist.com/article/temperature-measurement-for-patients-with-fever. Accessed: 2022-10-25.

[5]

[n. d.]. Thermometers: Understand the options. https://www.mayoclinic.org/diseases-conditions/fever/in-depth/thermometers/art-20046737. Accessed: 2022-07-31.

[6]

Anwar Ahmed and Birhanu Sintayehu. 2022. Implementation of Covid-19 protection protocols and its implication on learning & teaching in public schools. Heliyon 8, 5 (2022), e09362.

[7]

Forsad Al Hossain, Andrew A Lover, George A Corey, Nicholas G Reich, and Tauhidur Rahman. 2020. FluSense: a contactless syndromic surveillance platform for influenza-like illness in hospital waiting areas. Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies 4, 1 (2020), 1--28.

Digital Library

[8]

Diego Barrettino, Thomas Gisler, Christoph Zumbühl, Christian Di Battista, Raphael Kummer, and Markus Thalmann. 2020. Wearable Medical Device for Remote Monitoring the Health of Elderly People at Home. In 2020 IEEE International Instrumentation and Measurement Technology Conference (I2MTC). IEEE, 1--6.

Digital Library

[9]

Nivedita Bijlani, Ramin Nilforooshan, Samaneh Kouchaki, et al. 2022. An Unsupervised Data-Driven Anomaly Detection Approach for Adverse Health Conditions in People Living With Dementia: Cohort Study. JMIR aging 5, 3 (2022), e38211.

[10]

Guy Boivin, Isabelle Hardy, Guy Tellier, and Jean Maziade. 2000. Predicting influenza infections during epidemics with use of a clinical case definition. Clinical infectious diseases 31, 5 (2000), 1166--1169.

[11]

Joseph Breda and Shwetak Patel. 2021. Intuitive and Ubiquitous Fever Monitoring Using Smartphones and Smartwatches. arXiv preprint arXiv:2106.11855 (2021).

[12]

Joseph Breda, Amee Trivedi, Chulabhaya Wijesundara, Phuthipong Bovornkeeratiroj, David Irwin, Prashant Shenoy, and Jay Taneja. 2019. Hot or Not: Leveraging Mobile Devices for Ubiquitous Temperature Sensing. In Proceedings of the 6th ACM International Conference on Systems for Energy-Efficient Buildings, Cities, and Transportation. 41--50.

Digital Library

[13]

Nguyen Hai Chau. 2019. Estimation of air temperature using smartphones in different contexts. Journal of Information and Telecommunication 3, 4 (2019), 494--507.

[14]

Hsuan-Yu Chen, Andrew Chen, and Chiachung Chen. 2020. Investigation of the impact of infrared sensors on core body temperature monitoring by comparing measurement sites. Sensors 20, 10 (2020), 2885.

[15]

Charmaine Childs. 2018. Body temperature and clinical thermometry. Handbook of clinical neurology 157 (2018), 467--482.

[16]

Joon-Ho Choi and Vivian Loftness. 2012. Investigation of human body skin temperatures as a bio-signal to indicate overall thermal sensations. Building and Environment 58 (2012), 258--269.

[17]

Frances Doyle, W John Zehner, and Thomas E Terndrup. 1992. The effect of ambient temperature extremes on tympanic and oral temperatures. The American journal of emergency medicine 10, 4 (1992), 285--289.

[18]

Sarah Farnell, Lorraine Maxwell, Seok Tan, Andrew Rhodes, and Barbara Philips. 2005. Temperature measurement: Comparison of non-invasive methods used in adult critical care. Journal of Clinical Nursing 14, 5 (2005), 632--639.

[19]

Chen Ge, Xie Jiarong, Dai Guangli, Peijun Zheng, Hu Xiaqing, Lu Hongpeng, Xu Lei, Chen Xueqin, and Chen Xiaomin. 2020. Validity of the use of wrist and forehead temperatures in screening the general population for covid-19: A prospective real-world study. Iranian Journal of Public Health 49, Suppl 1 (2020), 57.

[20]

ThM Govaert, GJ Dinant, K Aretz, and JA Knottnerus. 1998. The predictive value of influenza symptomatology in elderly people. Family practice 15, 1 (1998), 16--22.

[21]

Kyra H Grantz, Hannah R Meredith, Derek AT Cummings, C Jessica E Metcalf, Bryan T Grenfell, John R Giles, Shruti Mehta, Sunil Solomon, Alain Labrique, Nishant Kishore, et al. 2020. The use of mobile phone data to inform analysis of COVID-19 pandemic epidemiology. Nature communications 11, 1 (2020), 1--8.

[22]

Amos Grünebaum, Frank A Chervenak, Laurence B McCullough, Joachim W Dudenhausen, Eran Bornstein, and Philip A Mackowiak. 2021. How fever is defined in COVID-19 publications: a disturbing lack of precision. Journal of Perinatal Medicine 49, 3 (2021), 255--261.

[23]

Wei-jie Guan, Zheng-yi Ni, Yu Hu, Wen-hua Liang, Chun-quan Ou, Jian-xing He, Lei Liu, Hong Shan, Chun-liang Lei, David SC Hui, et al. 2020. Clinical characteristics of coronavirus disease 2019 in China. New England journal of medicine 382, 18 (2020), 1708--1720.

[24]

Liang He, Youngmoon Lee, and Kang G Shin. 2020. Mobile device batteries as thermometers. Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies 4, 1 (2020), 1--21.

Digital Library

[25]

Robert P Hirten, Matteo Danieletto, Lewis Tomalin, Katie Hyewon Choi, Micol Zweig, Eddye Golden, Sparshdeep Kaur, Drew Helmus, Anthony Biello, Renata Pyzik, et al. 2021. Use of physiological data from a wearable device to identify SARS-CoV-2 infection and symptoms and predict COVID-19 diagnosis: observational study. Journal of medical Internet research 23, 2 (2021), e26107.

[26]

Minh Long Hoang, Marco Carratù, Vincenzo Paciello, and Antonio Pietrosanto. 2021. Body temperature---indoor condition monitor and activity recognition by MEMS accelerometer based on IoT-alert system for people in quarantine due to COVID-19. Sensors 21, 7 (2021), 2313.

[27]

Yoshitaka Inui, Satoshi Hirayama, and Tadashi Tanaka. 2019. Detailed estimation method of heat generation during charge/discharge in lithium-ion battery using equivalent circuit. Electronics and Communications in Japan 102, 12 (2019), 3--14.

Digital Library

[28]

Sanghoon Jun, Kilho Lee, and Jinkyu Lee. 2022. TherMobile: Measuring Body Temperature Using a Mobile Device. IEEE Sensors Journal (2022).

[29]

JA Kistemaker, EA Den Hartog, and HAM Daanen. 2006. Reliability of an infrared forehead skin thermometer for core temperature measurements. Journal of medical engineering & technology 30, 4 (2006), 252--261.

[30]

S Kohno, T Otsubo, K Hara, Y Tomii, and J Seki. 1995. Program and abstracts of the 35th Interscience Conference on Antimicrobial Agents and Chemotherapy. (1995).

[31]

Fan Lai, Xin Li, Qi Wang, Yingjuan Luo, Xin Wang, Xiuhua Huang, Jiajia Zhang, Jieru Peng, Qin Wang, Li Fan, et al. 2022. Reliability of Non-Contact Infrared Thermometers for Fever Screening Under COVID-19. Risk management and healthcare policy 15 (2022), 447.

[32]

Lari Lawson, Elizabeth J Bridges, Isabelle Ballou, Ruthe Eraker, Sheryl Greco, Janie Shively, and Vanessa Sochulak. 2007. Accuracy and precision of noninvasive temperature measurement in adult intensive care patients. American journal of critical care 16, 5 (2007), 485--496.

[33]

Yaguo Lei, Naipeng Li, Liang Guo, Ningbo Li, Tao Yan, and Jing Lin. 2018. Machinery health prognostics: A systematic review from data acquisition to RUL prediction. Mechanical systems and signal processing 104 (2018), 799--834.

[34]

Rainer Lenhardt and Daniel I Sessler. 2006. Estimation of mean body temperature from mean skin and core temperature. The Journal of the American Society of Anesthesiologists 105, 6 (2006), 1117--1121.

[35]

Christine E Long, Caroline B Hall, Coleen K Cunningham, Leonard B Weiner, Kathleen P Alger, Maria Gouveia, Carol B Colella, Kenneth C Schnabel, and William H Barker. 1997. Influenza surveillance in community-dwelling elderly compared with children. Archives of family medicine 6, 5 (1997), 459.

[36]

Alex Mariakakis, Edward Wang, Shwetak Patel, and Mayank Goel. 2019. Challenges in Realizing Smartphone-Based Health Sensing. IEEE Pervasive Computing 18, 2 (apr 2019), 76--84. https://doi.org/10.1109/MPRV.2019.2907007

Digital Library

[37]

Michela Masè, Andreas Werner, Gabriel Putzer, Giovanni Avancini, Marika Falla, Hermann Brugger, Alessandro Micarelli, and Giacomo Strapazzon. 2022. Low Ambient Temperature Exposition Impairs the Accuracy of a Non-invasive Heat-Flux Thermometer. Frontiers in Physiology (2022), 283.

[38]

Mike A Merrill and Tim Althoff. 2022. Self-supervised Pretraining and Transfer Learning Enable Flu and COVID-19 Predictions in Small Mobile Sensing Datasets. arXiv preprint arXiv:2205.13607 (2022).

[39]

Aaron C Miller, Inder Singh, Erin Koehler, and Philip M Polgreen. 2018. A smartphone-driven thermometer application for real-time population-and individual-level influenza surveillance. Clinical Infectious Diseases 67, 3 (2018), 388--397.

[40]

Ricardo Morán-Navarro, Javier Courel-Ibáñez, Alejandro Martínez-Cava, Elena Conesa-Ros, Alejandro Sánchez-Pay, Ricardo Mora-Rodriguez, and Jesús G Pallarés. 2019. Validity of skin, oral and tympanic temperatures during exercise in the heat: effects of wind and sweat. Annals of Biomedical Engineering 47, 1 (2019), 317--331.

[41]

Daniel J Niven, Jonathan E Gaudet, Kevin B Laupland, Kelly J Mrklas, Derek J Roberts, and Henry Thomas Stelfox. 2015. Accuracy of peripheral thermometers for estimating temperature: a systematic review and meta-analysis. Annals of internal medicine 163, 10 (2015), 768--777.

[42]

Aart Overeem, JC R. Robinson, Hidde Leijnse, Gert-Jan Steeneveld, BK P. Horn, and Remko Uijlenhoet. 2013. Crowdsourcing urban air temperatures from smartphone battery temperatures. Geophysical Research Letters 40, 15 (2013), 4081--4085.

[43]

RC Parmar, DR Sahu, SB Bavdekar, et al. 2001. Knowledge, attitude and practices of parents of children with febrile convulsion. Journal of postgraduate medicine 47, 1 (2001), 19.

[44]

Valentina Pecoraro, Davide Petri, Giorgio Costantino, Alessandro Squizzato, Lorenzo Moja, Gianni Virgili, and Ersilia Lucenteforte. 2021. The diagnostic accuracy of digital, infrared and mercury-in-glass thermometers in measuring body temperature: a systematic review and network meta-analysis. Internal and emergency medicine 16, 4 (2021), 1071--1083.

[45]

Sujit Shinde, Swapna Agarwal, Dibyanshu Jaiswal, Avik Ghose, Sanjay Kimbahune, and Pravin Pillai. 2020. ThermoTrak: smartphone based real-time fever screening: demo abstract. In Proceedings of the 18th Conference on Embedded Networked Sensor Systems. 639--640.

Digital Library

[46]

K Taylor and L Siliver. 2019. In Emerging Economies, Smartphone Adoption Has Grown More Quickly among Younger Generations. Pew Research Cetner, Feb 5 (2019).

[47]

Amee Trivedi, Phuthipong Bovornkeeratiroj, Joseph Breda, Prashant Shenoy, Jay Taneja, and David Irwin. [n. d.]. Phone-based ambient temperature sensing using opportunistic crowdsensing and machine learning. Sustainable Computing: Informatics and Systems 29 ([n. d.]), 100479.

[48]

Srinivasan Venkatramanan, Adam Sadilek, Arindam Fadikar, Christopher L Barrett, Matthew Biggerstaff, Jiangzhuo Chen, Xerxes Dotiwalla, Paul Eastham, Bryant Gipson, Dave Higdon, et al. 2021. Forecasting influenza activity using machine-learned mobility map. Nature communications 12, 1 (2021), 1--12.

[49]

Paul Webb. 1992. Temperatures of skin, subcutaneous tissue, muscle and core in resting men in cold, comfortable and hot conditions. European journal of applied physiology and occupational physiology 64, 5 (1992), 471--476.

[50]

Peter Wei, Chenye Yang, and Xiaofan Jiang. 2020. Low-cost multi-person continuous skin temperature sensing system for fever detection. In Proceedings of the 18th Conference on Embedded Networked Sensor Systems. 705--706.

Digital Library

Cited By

Xue QLiu YBreda JSpringston MIyer VPatel S(2024)Thermal EarringProceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies10.1145/36314407:4(1-28)Online publication date: 12-Jan-2024
https://dl.acm.org/doi/10.1145/3631440
Morshed MMahbubur Rahman MNathan VZhu LBae JRosa CMendes WKuang JGao A(2024)Core Body Temperature and its Role in Detecting Acute Stress: A Feasibility StudyICASSP 2024 - 2024 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)10.1109/ICASSP48485.2024.10447599(1606-1610)Online publication date: 14-Apr-2024
https://doi.org/10.1109/ICASSP48485.2024.10447599
Sarwar AAlmadani AAgu E(2024)Few-shot meta-learning for pre-symptomatic detection of Covid-19 from limited health tracker dataSmart Health10.1016/j.smhl.2024.10045932(100459)Online publication date: Jun-2024
https://doi.org/10.1016/j.smhl.2024.100459

Index Terms

FeverPhone: Accessible Core-Body Temperature Sensing for Fever Monitoring Using Commodity Smartphones
1. Applied computing
  1. Life and medical sciences
    1. Consumer health
2. Human-centered computing
  1. Ubiquitous and mobile computing
    1. Ubiquitous and mobile devices
      1. Smartphones

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cover image Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies

Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies Volume 7, Issue 1

March 2023

1243 pages

EISSN:2474-9567

DOI:10.1145/3589760

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Copyright © 2023 Owner/Author.

This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike International 4.0 License.

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Association for Computing Machinery

New York, NY, United States

Publication History

Published: 28 March 2023

Published in IMWUT Volume 7, Issue 1

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Cited By

Xue QLiu YBreda JSpringston MIyer VPatel S(2024)Thermal EarringProceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies10.1145/36314407:4(1-28)Online publication date: 12-Jan-2024
https://dl.acm.org/doi/10.1145/3631440
Morshed MMahbubur Rahman MNathan VZhu LBae JRosa CMendes WKuang JGao A(2024)Core Body Temperature and its Role in Detecting Acute Stress: A Feasibility StudyICASSP 2024 - 2024 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)10.1109/ICASSP48485.2024.10447599(1606-1610)Online publication date: 14-Apr-2024
https://doi.org/10.1109/ICASSP48485.2024.10447599
Sarwar AAlmadani AAgu E(2024)Few-shot meta-learning for pre-symptomatic detection of Covid-19 from limited health tracker dataSmart Health10.1016/j.smhl.2024.10045932(100459)Online publication date: Jun-2024
https://doi.org/10.1016/j.smhl.2024.100459

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