Abstract
Several new algorithms for camera-based fall detection have been proposed in the literature recently, with the aim to monitor older people at home so nurses or family members can be warned in case of a fall incident. However, these algorithms are evaluated almost exclusively on data captured in controlled environments, under optimal conditions (simple scenes, perfect illumination and setup of cameras), and with falls simulated by actors.
In contrast, we collected a dataset based on real life data, recorded at the place of residence of four older persons over several months. We showed that this poses a significantly harder challenge than the datasets used earlier. The image quality is typically low. Falls are rare and vary a lot both in speed and nature. We investigated the variation in environment parameters and context during the fall incidents. We found that various complicating factors, such as moving furniture or the use of walking aids, are very common yet almost unaddressed in the literature. Under such circumstances and given the large variability of the data in combination with the limited number of examples available to train the system, we posit that simple yet robust methods incorporating, where available, domain knowledge (e.g. the fact that the background is static or that a fall usually involves a downward motion) seem to be most promising. Based on these observations, we propose a new fall detection system. It is based on background subtraction and simple measures extracted from the dominant foreground object such as aspect ratio, fall angle and head speed. We discuss the results obtained, with special emphasis on particular difficulties encountered under real world circumstances.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
References
Anderson, D., Keller, J., Skubic, M., Chen, X., He, Z.: Recognizing falls from silhouettes. In: 28th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, EMBS 2006, pp. 6388–6391 (September 2006)
Cucchiara, R., Prati, A., Vezzani, R.: An intelligent surveillance system for dangerous situation detection in home environments. Intelligenza Artificiale 1(1), 11–15 (2004)
Felzenszwalb, P., Mcallester, D., Ramanan, D.: A discriminatively trained, multiscale, deformable part model. In: IEEE International Conference on Computer Vision and Pattern Recognition (CVPR) Anchorage, Alaska (June 2008)
Fleming, J., Brayne, C.: Inability to get up after falling, subsequent time on floor, and summoning help: prospective cohort study in people over 90. British Medicine Journal 337(v17 1), 2227 (2008)
Foroughi, H., Aski, B., Pourreza, H.: Intelligent video surveillance for monitoring fall detection of elderly in home environments. In: 11th International Conference on Computer and Information Technology, ICCIT 2008, pp. 219–224 (2008)
Grest, D., Frahm, J., Koch, R.: A color similarity measure for robust shadow removal in real-time. Vision, Modeling and Vizualization (2003)
Haentjens, P., Lamraski, G., Boonen, S.: Costs and consequences of hip fracture occurrence in old age: An economic perspective. Disability and Rehabilitation 27(18-19), 1129–1141 (2005)
Hartholt, K.A., van der Velde, N., Looman, C.W.N., van Lieshout, E.M.M., Panneman, M.J.M., van Beeck, E.F., Patka, P., van der Cammen, T.J.M.: Trends in fall-related hospital admissions in older persons in the netherlands. Arch. Intern. Med. 170(10), 905–911 (2010)
Jacques, J.C.S., Jung, C.R.: Background subtraction and shadow detection in grayscale video sequences. In: The XVIII Brazilian Symposium on Computer Graphics and Image Processing, SIBGRAPI 2005 (2005)
Lee, T., Mihailidis, A.: An intelligent emergency response system: preliminary development and testing of automated fall detection. Journal of Telemedicine and Telecare 11(4), 194–198 (2005)
McFarlane, N.J.B., Schofield, C.P.: Segmentation and tracking of piglets in images. Machine Vision and Applications 8(3), 187–193 (1995)
Miao, Y., Naqvi, S., Chambers, J.: Fall detection in the elderly by head tracking. In: IEEE/SP 15th Workshop on Statistical Signal Processing, SSP 2009, pp. 357–360 (September 2009)
Miaou, S.G., Sung, P.H., Huang, C.Y.: A customized human fall detection system using omni-camera images and personal information. Distributed Diagnosis and Home Healthcare, 39–42 (2006)
Milisen, K., Detroch, E., Bellens, K., Braes, T., Dierickx, K., Smeulders, W., Teughels, S., Dejaeger, E., Boonen, S., Pelemans, W.: Falls among community-dwelling elderly: a pilot study of prevalence, circumstances and consequences in flanders. Tijdschr Gerontol Geriatr 35(1), 15–20 (2004)
Nait-Charif, H., McKenna, S.J.: Activity summarisation and fall detection in a supportive home environment. In: ICPR 2004: 17th International Conference on Proceedings of the Pattern Recognition, vol. 4, pp. 323–326. IEEE Computer Society, Washington, DC (2004)
Nater, F., Grabner, H., Van Gool, L.: Visual abnormal event detection for prolonged independent living. In: International Mobile Health (mHealth) Workshop (2010)
Osuna, E., Freund, R., Girosi, F.: Support vector machines: Training and applications. AI Memo 1602, Massachusetts Institute of Technology (1997)
Rougier, C., Meunier, J., St-Arnaud, A., Rousseau, J.: Monocular 3d head tracking to detect falls of elderly people. In: Annual International Conference of the IEEE Engineering in Medicine and Biology Society (2006)
Rougier, C., Meunier, J., St-Arnaud, A., Rousseau, J.: Fall detection from human shape and motion history using video surveillance. In: 21st International Conference on Advanced Information Networking and Applications Workshops, AINAW 2007, vol. 2, pp. 875–880 (2007)
Scuffham, P., Chaplin, S., Legood, R.: Incidence and costs of unintentional falls in older people in the United Kingdom. J. Epidemiol. Community Health 57(9), 740–744 (2003)
SeniorWatch: Fall detector: Case study of european ist seniorwatch project. Tech. rep., SeniorWatch (2001)
Syngelakis, E., Collomosse, J.: A bag of features approach to ambient fall detection for domestic elder-care. In: Proc. Intl. Symp. on Ambient Technologies, AMBIENT 2011 (2011)
Thome, N., Miguet, S., Ambellouis, S.: A real-time, multiview fall detection system: A lhmm-based approach. IEEE Transactions on Circuits and Systems for Video Technology 18(11), 1522–1532 (2008)
Tinetti, M.E.: Preventing falls in elderly persons. New England Journal of Medicine 348(1), 42–49 (2003)
Töreyin, B.U., Dedeoğlu, Y., Çetin, A.E.: HMM Based Falling Person Detection Using Both Audio and Video. In: Sebe, N., Lew, M., Huang, T.S. (eds.) HCI/ICCV 2005. LNCS, vol. 3766, pp. 211–220. Springer, Heidelberg (2005)
Vapnik, V.: Statistical learning theory. Wiley, New York (1998)
Willems, J., Debard, G., Vanrumste, B., Goedemé, T.: A video-based algorithm for elderly fall detection. In: Medical Physics and Biomedical Engineering World Congress, WC 2009 (2009)
Yang, Y., Ramanan, D.: Articulated pose estimation with flexible mixtures-of-parts. In: 2011 IEEE Conference on Computer Vision and Pattern Recognition (CVPR), pp. 1385–1392 (June 2011)
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2012 Springer-Verlag Berlin Heidelberg
About this paper
Cite this paper
Debard, G. et al. (2012). Camera-Based Fall Detection on Real World Data. In: Dellaert, F., Frahm, JM., Pollefeys, M., Leal-Taixé, L., Rosenhahn, B. (eds) Outdoor and Large-Scale Real-World Scene Analysis. Lecture Notes in Computer Science, vol 7474. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-34091-8_16
Download citation
DOI: https://doi.org/10.1007/978-3-642-34091-8_16
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-642-34090-1
Online ISBN: 978-3-642-34091-8
eBook Packages: Computer ScienceComputer Science (R0)