Abstract
We live in a world surrounded by ubiquitous devices that capture data related to our daily activities. Being able to infer this data not only helps to recognise activities of daily life but can also allow the possibility to recognise any behavioural changes of the person being observed. This paper presents a performance comparison of a series of machine learning classification techniques for activity recognition. An existing hierarchal activity recognition framework has been adapted in order to assess the performance of five machine learning classification techniques. We performed extensive experiments and found that classification approaches significantly outperform traditional activity recognition approaches. The motivation of the work is to enable independent living among the elderly community, namely patients suffering from Alzheimer’s disease.
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Similar pattern of results were observed in case of two-fold cross validation. We did not show these results due to space constraint.
References
Alhamid MF, Saboune J, Alamri A, El Saddik A (2011) Hamon: an activity recognition framework for health monitoring support at home. In: 2011 IEEE instrumentation and measurement technology conference (I2MTC), May 2011, pp 1–5
Ali H, Messina E, Bisiani R (2013) Subject-dependent physical activity recognition model framework with a semi-supervised clustering approach. In: Seventh UK Sim/AMSS European modelling symposium, EMS 2013, Manchester UK, 20–22 Nov 2013, pp 42–47
Alvarez-Alvarez A, Alonso J-M, Trivio G, Hernandez N, Herranz F, Llamazares A, Ocaa M (2010) Human activity recognition applying computational intelligence techniques for fusing information related to wifi positioning and body posture. In: FUZZ-IEEE. IEEE, pp 1–8
Anjum A, Ilyas MU (2013) Activity recognition using smartphone sensors. In: 2013 IEEE consumer communications and networking conference (CCNC), Jan 2013, pp 914–919
Azam MA, Loo J, Lasebae A, Khan SKA, Ejaz W (2012) Tiered approach to infer the behaviour of low entropy mobile people. In: 2012 IEEE wireless communications and networking conference (WCNC), Apr 2012, pp 3334–3339
Azam MA, Loo J, Naeem U, Khan SKA, Lasebae A, Gemikonakli O (2012) A framework to recognise daily life activities with wireless proximity and object usage data. In: Proceedings of 23rd IEEE international symposium on personal, indoor and mobile radio communication
Borgetl C (2003) Efficient implementation of Apriori and Eclat. In: 1st IEEE ICDM workshop on frequent item set, p 9
Buettner M, Prasad R, Philipose M, Wetherall D (2009) Recognizing daily activities with RFID-based sensors. In: Helal S, Gellersen H, Consolvo S (eds) UbiComp, ACM international conference proceeding series. ACM, pp 51–60
Chen Y-H, Lu C-H, Hsu K-C, Fu L-C, Yeh Y-J, Kuo L-C (2009) Preference model assisted activity recognition learning in a smart home environment. In: IEEE/RSJ international conference on intelligent robots and systems, 2009, IROS 2009, Oct 2009, pp 4657–4662
Chen L, Hoey J, Nugent CD, Cook DJ, Yu Z (2012) Sensor-based activity recognition. IEEE Trans Syst Man Cybern Part C Appl Rev 42(6):790–808
Dalton AF, Laighin G (2013) Comparing supervised learning techniques on the task of physical activity recognition. IEEE J Biomed Health Inform 17(1):46–52
Fan L, Wang Z, Wang H (2013) Human activity recognition model based on decision tree. In: 2013 international conference on advanced cloud and big data (CBD), Dec 2013, pp 64–68
Ghazanfar MA, Prugel-Bennett A (2013) The advantage of careful imputation sources in sparse data-environment of recommender systems: generating improved SVD-based recommendations. Informatica 37(1):61–92
Ghose S, Barua JJ (2013) A systematic approach with data mining for analyzing physical activity for an activity recognition system. In: 2013 international conference on advances in electrical engineering (ICAEE), Dec 2013, pp 415–420
Guiry JJ, Van de Ven P, Nelson J (2012) Classification techniques for smartphone based activity detection. In: 2012 IEEE 11th international conference on cybernetic intelligent systems (CIS), Aug 2012, pp 154–158
He Z-Y, Jin L-W (2008) Activity recognition from acceleration data using a model representation and SVM. In: 2008 international conference on machine learning and cybernetics, July 2008, vol 4, pp 2245–2250
Khan ZA, Sohn W (2011) Abnormal human activity recognition system based on r-transform and kernel discriminant technique for elderly home care. IEEE Trans Consum Electron 57(4):1843–1850
Khan ZA, Sohn W (2012) Hierarchical human activity recognition system based on r-transform and nonlinear kernel discriminant features. Electron Lett 48(18):1119–1120
Khan A, Lawo M, Homer P (2013) Wearable recognition system for physical activities. In: The 9th international conference on intelligent environments—IE’13. IEEE, pp 245–249
Lustrek M, Cvetkovic B, Kozina S (2012) Energy expenditure estimation with wearable accelerometers. In: 2012 IEEE international symposium on circuits and systems (ISCAS), May 2012, pp 5–8
Marschollek M, Ludwig W, Schapiewksi I, Schriever E, Schubert R, Dybowski H, Schwabedissen HM, Howe J, Haux R (2007) Multimodal home monitoring of elderly people—first results from the lass study. In: 21st international conference on advanced information networking and applications workshops, 2007, AINAW’07, May 2007, vol 2, pp 815–819
Mazilu S, Hardegger M, Zhu Z, Roggen D, Troester G, Plotnik M, Hausdorff J (2012) Online detection of freezing of gait with smartphones and machine learning techniques. In: 6th international conference on pervasive computing technologies for healthcare. IEEE
Moller A, Roalter L, Diewald S, Scherr J, Kranz M, Hammerla N, Olivier P, Plotz T (2012) Gymskill: A personal trainer for physical exercises. In: 2012 IEEE international conference on pervasive computing and communications (PerCom), Mar 2012, pp 213–220
Nasreen S (2013) An improved hierarchical framework for recognizing indoor daily life activities. Master’s thesis, Department of Software Engineering, UET Taxila
Santhiranayagam BK, Lai DTH, Jiang C, Shilton A, Begg R (2012) Automatic detection of different walking conditions using inertial sensor data. In: The 2012 international joint conference on neural networks (IJCNN), June 2012, pp 1–6
Storf H, Becker M, Riedl M (2009) Rule-based activity recognition framework: challenges, technique and learning. In: 3rd international conference on pervasive computing technologies for healthcare, Pervasive Health 2009, London, UK, 1–3 Apr 2009, pp 1–7, 2009
Taylor PE, Almeida GJM, Hodgins JK, Kanade T (2012) Multi-label classification for the analysis of human motion quality. In: 2012 annual international conference of the IEEE Engineering in Medicine and Biology Society (EMBC). IEEE, pp 2214–2218
Tirkaz C, Bruckner D, Yin GQ, Haase J (2012) Activity recognition using a hierarchical model. In: IECON 2012—38th annual conference on IEEE Industrial Electronics Society, Oct 2012, pp 2814–2820
Yang J, Wang S, Chen N, Chen X, Shi P (2010) Wearable accelerometer based extendable activity recognition system. In: 2010 IEEE international conference on robotics and automation (ICRA), May 2010, pp 3641–3647
Zahra S, Ghazanfar MA, Khalid A, Azam MA, Naeem U, Prugel-Bennett A (2015) Novel centroid selection approaches for k-means-clustering based recommender systems. Inf Sci 320:156–189
Zaki MJ (2000) Scalable algorithms for association mining. IEEE Trans Knowl Data Eng 12(3):372–390
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Hussain, R.G., Ghazanfar, M.A., Azam, M.A. et al. A performance comparison of machine learning classification approaches for robust activity of daily living recognition. Artif Intell Rev 52, 357–379 (2019). https://doi.org/10.1007/s10462-018-9623-5
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DOI: https://doi.org/10.1007/s10462-018-9623-5