TY - JOUR
T1 - Modeling occupant behavior in buildings
AU - Carlucci, Salvatore
AU - De Simone, Marilena
AU - Firth, Steven K.
AU - Kjærgaard, Mikkel B.
AU - Markovic, Romana
AU - Rahaman, Mohammad Saiedur
AU - Annaqeeb, Masab Khalid
AU - Biandrate, Silvia
AU - Das, Anooshmita
AU - Dziedzic, Jakub Wladyslaw
AU - Fajilla, Gianmarco
AU - Favero, Matteo
AU - Ferrando, Martina
AU - Hahn, Jakob
AU - Han, Mengjie
AU - Peng, Yuzhen
AU - Salim, Flora
AU - Schlüter, Arno
AU - van Treeck, Christoph
PY - 2020/5
Y1 - 2020/5
N2 - In the last four decades several methods have been used to model occupants' presence and actions (OPA) in buildings according to different purposes, available computational power, and technical solutions. This study reviews approaches, methods and key findings related to OPA modeling in buildings. An extensive database of related research documents is systematically constructed, and, using bibliometric analysis techniques, the scientific production and landscape are described. The initial literature screening identified more than 750 studies, out of which 278 publications were selected. They provide an overarching view of the development of OPA modeling methods. The research field has evolved from longitudinal collaborative efforts since the late 1970s and, so far, covers diverse building typologies mostly concentrated in a few climate zones. The modeling approaches in the selected literature are grouped into three categories (rule-based models, stochastic OPA modeling, and data-driven methods) for modeling occupancy-related target functions and a set of occupants’ actions (window, solar shading, electric lighting, thermostat adjustment, clothing adjustment and appliance use). The explanatory modeling is conventionally based on the model-based paradigm where occupant behavior is assumed to be stochastic, while the data-driven paradigm has found wide applications for the predictive modeling of OPA, applicable to control systems. The lack of established standard evaluation protocols was identified as a scientifically important yet rarely addressed research question. In addition, machine learning and deep learning are emerging in recent years as promising methods to address OPA modeling in real-world applications.
AB - In the last four decades several methods have been used to model occupants' presence and actions (OPA) in buildings according to different purposes, available computational power, and technical solutions. This study reviews approaches, methods and key findings related to OPA modeling in buildings. An extensive database of related research documents is systematically constructed, and, using bibliometric analysis techniques, the scientific production and landscape are described. The initial literature screening identified more than 750 studies, out of which 278 publications were selected. They provide an overarching view of the development of OPA modeling methods. The research field has evolved from longitudinal collaborative efforts since the late 1970s and, so far, covers diverse building typologies mostly concentrated in a few climate zones. The modeling approaches in the selected literature are grouped into three categories (rule-based models, stochastic OPA modeling, and data-driven methods) for modeling occupancy-related target functions and a set of occupants’ actions (window, solar shading, electric lighting, thermostat adjustment, clothing adjustment and appliance use). The explanatory modeling is conventionally based on the model-based paradigm where occupant behavior is assumed to be stochastic, while the data-driven paradigm has found wide applications for the predictive modeling of OPA, applicable to control systems. The lack of established standard evaluation protocols was identified as a scientifically important yet rarely addressed research question. In addition, machine learning and deep learning are emerging in recent years as promising methods to address OPA modeling in real-world applications.
KW - Data-driven methods
KW - Deep learning
KW - Machine learning
KW - Occupant behavior
KW - PRISMA
KW - Stochastic methods
U2 - 10.1016/j.buildenv.2020.106768
DO - 10.1016/j.buildenv.2020.106768
M3 - Journal article
AN - SCOPUS:85081136131
SN - 0360-1323
VL - 174
JO - Building and Environment
JF - Building and Environment
M1 - 106768
ER -