At the Flick of a Switch: Detecting and Classifying Unique Electrical Events on the Residential Power Line (Nominated for the Best Paper Award)

Activity sensing in the home has a variety of important applications, including healthcare, entertainment, home automation, energy monitoring and post-occupancy research studies. Many existing systems for detecting occupant activity require large numbers of sensors, invasive vision systems, or extensive installation procedures. We present an approach that uses a single plug-in sensor to detect a variety of electrical events throughout the home. This sensor detects the electrical noise on residential power lines created by the abrupt switching of electrical devices and the noise created by certain devices while in operation. We use machine learning techniques to recognize electrically noisy events such as turning on or off a particular light switch, a television set, or an electric stove. We tested our system in one home for several weeks and in five homes for one week each to evaluate the system performance over time and in different types of houses. Results indicate that we can learn and classify various electrical events with accuracies ranging from 85-90%.

[1]  Elizabeth D. Mynatt,et al.  Digital Family Portrait Field Trial: Support for Aging in Place , 2005, CHI.

[2]  Colleen McCue,et al.  3 – Data Mining , 2007 .

[3]  Kent Larson,et al.  The Design of a Portable Kit of Wireless Sensors for Naturalistic Data Collection , 2006, Pervasive.

[4]  Nigel Davies,et al.  UbiComp 2004: Ubiquitous Computing , 2004, Lecture Notes in Computer Science.

[5]  Gregory D. Abowd,et al.  Privacy and proportionality: adapting legal evaluation techniques to inform design in ubiquitous computing , 2005, CHI.

[6]  Cambridge Ma,et al.  Some Novel Applications for Wireless Inertial Sensors , 2006 .

[7]  James Fogarty,et al.  Sensing from the basement: a feasibility study of unobtrusive and low-cost home activity recognition , 2006, UIST.

[8]  Emmanuel,et al.  Activity recognition in the home setting using simple and ubiquitous sensors , 2003 .

[9]  Uwe Hansmann,et al.  Pervasive Computing , 2003 .

[10]  Sunny Consolvo,et al.  Some Assembly Required: Supporting End-User Sensor Installation in Domestic Ubiquitous Computing Environments , 2004, UbiComp.

[11]  E. Howell How Switches Produce Electrical Noise , 1979, IEEE Transactions on Electromagnetic Compatibility.

[12]  Christopher G. Atkeson,et al.  Simultaneous Tracking and Activity Recognition (STAR) Using Many Anonymous, Binary Sensors , 2005, Pervasive.

[13]  Kent Larson,et al.  Activity Recognition in the Home Using Simple and Ubiquitous Sensors , 2004, Pervasive.

[14]  Elaine B. Hyder,et al.  The ELDer project: social, emotional, and environmental factors in the design of eldercare technologies , 2000, CUU '00.

[15]  Gregory D. Abowd,et al.  PowerLine Positioning: A Practical Sub-Room-Level Indoor Location System for Domestic Use , 2006, UbiComp.

[16]  Konrad Tollmar,et al.  Activity Zones for Context-Aware Computing , 2003, UbiComp.

[17]  James M. Rehg,et al.  Using Sound Source Localization in a Home Environment , 2005, Pervasive.

[18]  Ning Liu,et al.  Bathroom Activity Monitoring Based on Sound , 2005, Pervasive.

[19]  Anind K. Dey,et al.  UbiComp 2003: Ubiquitous Computing , 2003, Lecture Notes in Computer Science.