TY - GEN
T1 - On the Applicability of Ant Colony Optimization to Non-Intrusive Load Monitoring in Smart Grids
AU - Gonzalez-Pardo, Antonio
AU - Del Ser, Javier
AU - Camacho, David
N1 - Publisher Copyright:
© Springer International Publishing Switzerland 2015.
PY - 2015/11
Y1 - 2015/11
N2 - Along with the proliferation of the Smart Grid, power load disaggregation is a research area that is lately gaining a lot of popularity due to the interest of energy distribution companies and customers in identifying consumption patterns towards improving the way the energy is produced and consumed (via e.g. demand side management strategies). Such data can be extracted by using smartmeters, but the expensive cost of incorporating a monitoring device for each appliance jeopardizes significantly the massive implementation of any straightforward approach. When resorting to a single meter to monitor the global consumption of
the house at hand, the identification of the different appliances giving rise to the recorded consumption profile renders a particular instance of
the so-called source separation problem, for which a number of algorithmic proposals have been reported in the literature. This paper gravitates
on the applicability of the Ant Colony Optimization (ACO) algorithm to perform this power disaggregation treating the problem as a Constraint
Satisfaction Problem (CSP). The discussed experimental results utilize data contained in the REDD dataset, which corresponds to real power
consumption traces of different households. Although the experiments carried out in this work reveal that the ACO solver can be successfully
applied to the Non-Intrusive Load Monitoring problems, further work is needed towards assessing its performance when tackling more diversea ppliance models and noisy power load traces.
AB - Along with the proliferation of the Smart Grid, power load disaggregation is a research area that is lately gaining a lot of popularity due to the interest of energy distribution companies and customers in identifying consumption patterns towards improving the way the energy is produced and consumed (via e.g. demand side management strategies). Such data can be extracted by using smartmeters, but the expensive cost of incorporating a monitoring device for each appliance jeopardizes significantly the massive implementation of any straightforward approach. When resorting to a single meter to monitor the global consumption of
the house at hand, the identification of the different appliances giving rise to the recorded consumption profile renders a particular instance of
the so-called source separation problem, for which a number of algorithmic proposals have been reported in the literature. This paper gravitates
on the applicability of the Ant Colony Optimization (ACO) algorithm to perform this power disaggregation treating the problem as a Constraint
Satisfaction Problem (CSP). The discussed experimental results utilize data contained in the REDD dataset, which corresponds to real power
consumption traces of different households. Although the experiments carried out in this work reveal that the ACO solver can be successfully
applied to the Non-Intrusive Load Monitoring problems, further work is needed towards assessing its performance when tackling more diversea ppliance models and noisy power load traces.
KW - Non-intrusive load monitoring
KW - Ant colony optimization
KW - Power consumption disaggregation
KW - Non-intrusive load monitoring
KW - Ant colony optimization
KW - Power consumption disaggregation
UR - http://www.scopus.com/inward/record.url?scp=84952647408&partnerID=8YFLogxK
U2 - 10.1007/978-3-319-24598-0_28
DO - 10.1007/978-3-319-24598-0_28
M3 - Conference contribution
SN - 978-3-319-24597-3
SN - 9783319245973
T3 - 0302-9743
SP - 312
EP - 321
BT - unknown
A2 - Puerta, José M.
A2 - Gámez, José A.
A2 - Dorronsoro, Bernabé
A2 - Baruque, Bruno
A2 - Troncoso, Alicia
A2 - Barrenechea, Edurne
A2 - Galar, Mikel
PB - Springer Berlin Heidelberg
T2 - 16th Conference of the Spanish Association for Artificial Intelligence, CAEPIA 2015
Y2 - 9 November 2015 through 12 November 2015
ER -