ActiviSee: Activity Transition Detection for Human Users through Wearable Sensor-augmented Glasses
Pages 371 - 378
Abstract
Falls are the biggest threat among all events to elderly people and patients and pose a serious risk to their well-being, confidence, and mortality. Visual impairments which distort depth perceptions are often identified as major reasons for falls. Single and/or multi-focal length glasses used to correct myopia (blurriness of distance vision) and presbyopia (blurriness of near vision) cause distorted depth perceptions if not used properly. Users, especially older adults, need to change between glasses while transitioning between sedentary to mobile activities and vice versa. Forgetting to change into proper glasses may lead to fall. In this paper, we plan to develop a novel system called Activisee which uses sensor-augmented glasses to automatically detect activity transitions and alert users to change into appropriate glasses whenever necessary. Although, wireless sensor systems have long been used for fall detection and prevention through human activity recognition, using sensor-augmented glasses for activity transition detection has never been studied. Results using data collected from 23 human users performing a set of five distinct activities show that Activisee can successfully detect transitions from sedentary to mobile activities with up to 92% accuracy.
References
[1]
Alex Black and Joanne Wood. 2005. Vision and falls. Clinical and Experimental Optometry 88, 4 (2005), 212–222.
[2]
Abby Brayton-Chung, Dennis Tomashek, and Roger O. Smith. 2013. Fall Risk Assessment: Development of a Paradigm to Measure Multifocal Eyeglass Effects. Physical & Occupational Therapy In Geriatrics 31, 1 (2013), 47–60. https://doi.org/10.3109/02703181.2012.763200 arXiv:https://doi.org/10.3109/02703181.2012.763200
[3]
Robert G Cumming, Catherine Sherrington, Stephen R Lord, Judy M Simpson, Constance Vogler, Ian D Cameron, and Vasi Naganathan. 2008. Cluster randomised trial of a targeted multifactorial intervention to prevent falls among older people in hospital. Bmj 336, 7647 (2008), 758–760.
[4]
Friedrich Foerster, Manfred Smeja, and Jochen Fahrenberg. 1999. Detection of posture and motion by accelerometry: a validation study in ambulatory monitoring. Computers in human behavior 15, 5 (1999), 571–583.
[5]
Emma Fortune, Marie Tierney, Cliodhna Ni Scanaill, Ala Bourke, Norelee Kennedy, and John Nelson. 2011. Activity level classification algorithm using SHIMMER™ wearable sensors for individuals with rheumatoid arthritis. In 2011 Annual International Conference of the IEEE Engineering in Medicine and Biology Society. 3059–3062. https://doi.org/10.1109/IEMBS.2011.6090836
[6]
Mark J Haran, Ian D Cameron, Rebecca Q Ivers, Judy M Simpson, Bonsan B Lee, Michael Tanzer, Mamta Porwal, Marcella MS Kwan, Connie Severino, and Stephen R Lord. 2010. Effect on falls of providing single lens distance vision glasses to multifocal glasses wearers: VISIBLE randomised controlled trial. Bmj 340 (2010).
[7]
Jihoon Hong and Tomoaki Ohtsuki. 2011. A state classification method based on space-time signal processing using SVM for wireless monitoring systems. In 2011 IEEE 22nd International Symposium on Personal, Indoor and Mobile Radio Communications. IEEE, 2229–2233.
[8]
Shoya Ishimaru, Kai Kunze, Koichi Kise, Jens Weppner, Andreas Dengel, Paul Lukowicz, and Andreas Bulling. 2014. In the blink of an eye: combining head motion and eye blink frequency for activity recognition with google glass. In Proceedings of the 5th augmented human international conference. 1–4.
[9]
Shoya Ishimaru, Kai Kunze, Katsuma Tanaka, Yuji Uema, Koichi Kise, and Masahiko Inami. 2015. Smart eyewear for interaction and activity recognition. In Proceedings of the 33rd Annual ACM Conference Extended Abstracts on Human Factors in Computing Systems. 307–310.
[10]
CN Joseph, S Kokulakumaran, K Srijeyanthan, A Thusyanthan, C Gunasekara, and CD Gamage. 2010. A framework for whole-body gesture recognition from video feeds. In 2010 5th international conference on industrial and information systems. IEEE, 430–435.
[11]
Kathryn E Kelly, Cheryl L Phillips, Kevin C Cain, Nayak L Polissar, and Paul B Kelly. 2002. Evaluation of a nonintrusive monitor to reduce falls in nursing home patients. Journal of the American Medical Directors Association 3, 6 (2002), 377–382.
[12]
Oussama Kerdjidj, Naeem Ramzan, Khalida Ghanem, Abbes Amira, and Fatima Chouireb. 2020. Fall detection and human activity classification using wearable sensors and compressed sensing. Journal of Ambient Intelligence and Humanized Computing 11, 1 (2020), 349–361.
[13]
N.M. Kosse, K. Brands, J.M. Bauer, T. Hortobagyi, and C.J.C. Lamoth. 2013. Sensor technologies aiming at fall prevention in institutionalized old adults: A synthesis of current knowledge. International Journal of Medical Informatics 82, 9 (2013), 743–752. https://doi.org/10.1016/j.ijmedinf.2013.06.001
[14]
Oscar D Lara and Miguel A Labrador. 2012. A survey on human activity recognition using wearable sensors. IEEE communications surveys & tutorials 15, 3 (2012), 1192–1209.
[15]
Sian Lun Lau and Klaus David. 2010. Movement recognition using the accelerometer in smartphones. In Future Network and Mobile Summit, 2010. IEEE, 1–9.
[16]
Qiang Li, John A Stankovic, Mark A Hanson, Adam T Barth, John Lach, and Gang Zhou. 2009. Accurate, fast fall detection using gyroscopes and accelerometer-derived posture information. In 2009 Sixth International Workshop on Wearable and Implantable Body Sensor Networks. IEEE, 138–143.
[17]
Stephen R Lord, Julia Dayhew, B App Sc, and Amelia Howland. 2002. Multifocal glasses impair edge-contrast sensitivity and depth perception and increase the risk of falls in older people. Journal of the American Geriatrics Society 50, 11 (2002), 1760–1766.
[18]
Stephen R. Lord, Catherine Sherrington, Hylton B. Menz, and Jacqueline C. T. Close. 2007. Falls in Older People: Risk Factors and Strategies for Prevention (2 ed.). Cambridge University Press. https://doi.org/10.1017/CBO9780511722233
[19]
Stephen R Lord, Stuart T Smith, and Jasmine C Menant. 2010. Vision and falls in older people: risk factors and intervention strategies. Clinics in geriatric medicine 26, 4 (2010), 569–581.
[20]
Sun Luqian and Zhao Yuyuan. 2021. Human Activity Recognition Using Time Series Pattern Recognition Model-Based on Tsfresh Features. In 2021 International Wireless Communications and Mobile Computing (IWCMC). IEEE, 1035–1040.
[21]
Briana Moreland, Ramakrishna Kakara, and Ankita Henry. 2020. Trends in nonfatal falls and fall-related injuries among adults aged ≥ 65 years—United States, 2012–2018. Morbidity and Mortality Weekly Report 69, 27 (2020), 875.
[22]
Koray Ozcan, Anvith Katte Mahabalagiri, Mauricio Casares, and Senem Velipasalar. 2013. Automatic fall detection and activity classification by a wearable embedded smart camera. IEEE journal on emerging and selected topics in circuits and systems 3, 2 (2013), 125–136.
[23]
Jehad Sarkar, Young-Koo Lee, Sungyoung Lee, 2011. GPARS: A general-purpose activity recognition system. Applied Intelligence 35, 2 (2011), 242–259.
[24]
Andrei Tolstikov, Xin Hong, Jit Biswas, Chris Nugent, Liming Chen, and Guido Parente. 2011. Comparison of fusion methods based on dst and dbn in human activity recognition. Journal of Control Theory and Applications 9, 1 (2011), 18–27.
[25]
TLM Van Kasteren, Gwenn Englebienne, and Ben JA Kröse. 2010. An activity monitoring system for elderly care using generative and discriminative models. Personal and ubiquitous computing 14, 6 (2010), 489–498.
[26]
Jaeyoung Yang, Joonwhan Lee, and Joongmin Choi. 2011. Activity recognition based on RFID object usage for smart mobile devices. Journal of Computer Science and Technology 26, 2 (2011), 239–246.
[27]
Zhenyu Zhao, Radhika Anand, and Mallory Wang. 2019. Maximum relevance and minimum redundancy feature selection methods for a marketing machine learning platform. In 2019 IEEE International Conference on Data Science and Advanced Analytics (DSAA). IEEE, 442–452.
[28]
Chun Zhu and Weihua Sheng. 2011. Wearable sensor-based hand gesture and daily activity recognition for robot-assisted living. IEEE Transactions on Systems, Man, and Cybernetics-Part A: Systems and Humans 41, 3 (2011), 569–573.
Index Terms
- ActiviSee: Activity Transition Detection for Human Users through Wearable Sensor-augmented Glasses
Recommendations
Elderly Assistance Using Wearable Sensors by Detecting Fall and Recognizing Fall Patterns
UbiComp '18: Proceedings of the 2018 ACM International Joint Conference and 2018 International Symposium on Pervasive and Ubiquitous Computing and Wearable ComputersFalling is a serious threat to the elderly people. One severe fall can cause hazardous problems like bone fracture or may lead to some permanent disability or even death. Thus, it has become the need of the hour to continuously monitor the activities of ...
Towards unobtrusive detection and realistic attribute analysis of daily activity sequences using a finger-worn device
Detection and analysis of activities of daily living (ADLs) are important in activity tracking, security monitoring, and life support in elderly healthcare. Recently, many research projects have employed wearable devices to detect and analyze ADLs. ...
Promoting Social Connectedness through Human Activity-Based Ambient Displays
ITAP '16: Proceedings of the International Symposium on Interactive Technology and Ageing PopulationsExisting research in ambient assisted living (AAL) confirms the success of context aware applications in conveying feelings of connectedness and creating a sense of co-presence. Awareness of an elder's activities could trigger emotional responses and ...
Comments
Please enable JavaScript to view thecomments powered by Disqus.Information & Contributors
Information
Published In
September 2022
538 pages
ISBN:9781450394239
DOI:10.1145/3544793
Copyright © 2022 ACM.
Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]
Sponsors
Publisher
Association for Computing Machinery
New York, NY, United States
Publication History
Published: 24 April 2023
Check for updates
Author Tags
Qualifiers
- Research-article
- Research
- Refereed limited
Conference
UbiComp/ISWC '22
Sponsor:
UbiComp/ISWC '22: The 2022 ACM International Joint Conference on Pervasive and Ubiquitous Computing
September 11 - 15, 2022
Cambridge, United Kingdom
Acceptance Rates
Overall Acceptance Rate 764 of 2,912 submissions, 26%
Contributors
Other Metrics
Bibliometrics & Citations
Bibliometrics
Article Metrics
- 0Total Citations
- 295Total Downloads
- Downloads (Last 12 months)217
- Downloads (Last 6 weeks)20
Reflects downloads up to 18 Nov 2024
Other Metrics
Citations
Cited By
View allView Options
View options
View or Download as a PDF file.
PDFeReader
View online with eReader.
eReaderHTML Format
View this article in HTML Format.
HTML FormatLogin options
Check if you have access through your login credentials or your institution to get full access on this article.
Sign in