Activity Inference for Ambient Intelligence Through Handling Artifacts in a Healthcare Environment

Human activity inference is not a simple process due to distinct ways of performing it. Our proposal presents the SCAN framework for activity inference. SCAN is divided into three modules: (1) artifact recognition, (2) activity inference, and (3) activity representation, integrating three important elements of Ambient Intelligence (AmI) (artifact-behavior modeling, event interpretation and context extraction). The framework extends the roaming beat (RB) concept by obtaining the representation using three kinds of technologies for activity inference. The RB is based on both analysis and recognition from artifact behavior for activity inference. A practical case is shown in a nursing home where a system affording 91.35% effectiveness was implemented in situ. Three examples are shown using RB representation for activity representation. Framework description, RB description and CALog system overcome distinct problems such as the feasibility to implement AmI systems, and to show the feasibility for accomplishing the challenges related to activity recognition based on artifact recognition. We discuss how the use of RBs might positively impact the problems faced by designers and developers for recovering information in an easier manner and thus they can develop tools focused on the user.

[1]  Henry A. Kautz,et al.  Inferring activities from interactions with objects , 2004, IEEE Pervasive Computing.

[2]  Kevin Curran,et al.  Context-Awareness in Ambient Intelligence , 2010, Int. J. Ambient Comput. Intell..

[3]  P. Alli,et al.  An Overview of Research Issues in the Modern Healthcare Monitoring System Design using Wireless Body area Network , 2012 .

[4]  Tom Rodden,et al.  Moving out from the control room: ethnography in system design , 1994, CSCW '94.

[5]  Monica Tentori,et al.  Artifacts' roaming beats recognition for estimating care activities in a nursing home , 2010, 2010 4th International Conference on Pervasive Computing Technologies for Healthcare.

[6]  Yanjun Qi,et al.  Automated analysis of nursing home observations , 2004, IEEE Pervasive Computing.

[7]  Anselm L. Strauss,et al.  Basics of qualitative research : techniques and procedures for developing grounded theory , 1998 .

[8]  Alberto L. Morán,et al.  Providing Awareness of Elder's Situations of Care through a Context-Aware Notification Environment: A Preliminary Evaluation , 2010, 2010 Sixth International Conference on Intelligent Environments.

[9]  Jesús Favela,et al.  Activity Recognition for the Smart Hospital , 2008, IEEE Intelligent Systems.

[10]  Juan Carlos Augusto,et al.  Ambient Intelligence—the Next Step for Artificial Intelligence , 2008, IEEE Intelligent Systems.

[11]  Paul Dourish,et al.  Implications for design , 2006, CHI.

[12]  Guanling Chen,et al.  A Survey of Context-Aware Mobile Computing Research , 2000 .

[13]  Josef Hallberg,et al.  Wearable systems in nursing home care: prototyping experience , 2006, IEEE Pervasive Computing.

[14]  Javier Bajo,et al.  GerAmi: Improving Healthcare Delivery in Geriatric Residences , 2008, IEEE Intelligent Systems.

[15]  Gian Luca Foresti,et al.  Ambient Intelligence: A Novel Paradigm , 2004 .

[16]  Henrik Bærbak Christensen,et al.  Using Logic Programming to Detect Activities in Pervasive Healthcare , 2002, ICLP.

[17]  Diane J. Cook,et al.  Human Activity Recognition and Pattern Discovery , 2010, IEEE Pervasive Computing.

[18]  Steve Benford,et al.  Supporting ethnographic studies of ubiquitous computing in the wild , 2006, DIS '06.

[19]  Bahram Javidi,et al.  Composite Fourier-plane nonlinear filter for distortion-invariant pattern recognition , 1997 .

[20]  N. Hoffart Basics of Qualitative Research: Techniques and Procedures for Developing Grounded Theory , 2000 .

[21]  Alex Pentland,et al.  Human computing and machine understanding of human behavior: a survey , 2006, ICMI '06.

[22]  Bahram Javidi,et al.  Distortion-invariant pattern recognition with Fourier-plane nonlinear filters. , 1996, Applied optics.

[23]  M. Alwan,et al.  Psychosocial Impact of Passive Health Status Monitoring on Informal Caregivers and Older Adults Living in Independent Senior Housing , 2006, 2006 2nd International Conference on Information & Communication Technologies.

[24]  Didier Stricker,et al.  Activity Recognition Using Biomechanical Model Based Pose Estimation , 2010, EuroSSC.

[25]  Ling Bao,et al.  Activity Recognition from User-Annotated Acceleration Data , 2004, Pervasive.

[26]  Mei-Ju Su,et al.  A Study of Ubiquitous Monitor with RFID in an Elderly Nursing Home , 2007, 2007 International Conference on Multimedia and Ubiquitous Engineering (MUE'07).

[27]  Gregory D. Abowd,et al.  Towards a Better Understanding of Context and Context-Awareness , 1999, HUC.

[28]  Jian Lu,et al.  epSICAR: An Emerging Patterns based approach to sequential, interleaved and Concurrent Activity Recognition , 2009, 2009 IEEE International Conference on Pervasive Computing and Communications.

[29]  Matthai Philipose,et al.  Common Sense Based Joint Training of Human Activity Recognizers , 2007, IJCAI.

[30]  Susanne Bødker,et al.  Applying activity theory to video analysis: how to make sense of video data in human-computer interaction , 1995 .

[31]  Mohan Rajesh Elara,et al.  A semi autonomous control and monitoring system for bed sores prevention , 2007, i-CREATe '07.

[32]  Guang-Zhong Yang,et al.  Sensor Positioning for Activity Recognition Using Wearable Accelerometers , 2011, IEEE Transactions on Biomedical Circuits and Systems.

[33]  Richard J. Duro,et al.  UniDA: Uniform Device Access Framework for Human Interaction Environments , 2011, Italian National Conference on Sensors.

[34]  Giuseppe De Pietro,et al.  Formal Design of Ambient Intelligence Applications , 2010, Computer.