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W3128328166 startingPage "447" @default.
W3128328166 abstract "The power scheduling problem in a smart home (PSPSH) refers to the timely scheduling operations of smart home appliances under a set of restrictions and a dynamic pricing scheme(s) produced by a power supplier company (PSC). The primary objectives of PSPSH are: (I) minimizing the cost of the power consumed by home appliances, which refers to electricity bills, (II) balance the power consumed during a time horizon, particularly at peak periods, which is known as the peak-to-average ratio, and (III) maximizing the satisfaction level of users. Several approaches have been proposed to address PSPSH optimally, including optimization and non-optimization based approaches. However, the set of restrictions inhibit the approach used to obtain the optimal solutions. In this paper, a new formulation for smart home battery (SHB) is proposed for PSPSH that reduces the effect of restrictions in obtaining the optimal/near-optimal solutions. SHB can enhance the scheduling of smart home appliances by storing power at unsuitable periods and use the stored power at suitable periods for PSPSH objectives. PSPSH is formulated as a multi-objective optimization problem to achieve all objectives simultaneously. A robust swarm-based optimization algorithm inspired by the grey wolf lifestyle called grey wolf optimizer (GWO) is adapted to address PSPSH. GWO has powerful operations managed by its dynamic parameters that maintain exploration and exploitation behavior in search space. Seven scenarios of power consumption and dynamic pricing schemes are considered in the simulation results to evaluate the proposed multi-objective PSPSH using SHB (BMO-PSPSH) approach. The proposed BMO-PSPSH approach’s performance is compared with that of other 17 state-of-the-art algorithms using their recommended datasets and four algorithms using the proposed datasets. The proposed BMO-PSPSH approach exhibits and yields better performance than the other compared algorithms in almost all scenarios." @default.
W3128328166 created "2021-02-15" @default.
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W3128328166 date "2021-02-11" @default.
W3128328166 modified "2023-10-10" @default.
W3128328166 title "Smart Home Battery for the Multi-Objective Power Scheduling Problem in a Smart Home Using Grey Wolf Optimizer" @default.
W3128328166 cites W1564666037 @default.
W3128328166 cites W1963659584 @default.
W3128328166 cites W1976795412 @default.
W3128328166 cites W1994226661 @default.
W3128328166 cites W1997188340 @default.
W3128328166 cites W2018633335 @default.
W3128328166 cites W2025904793 @default.
W3128328166 cites W2027360559 @default.
W3128328166 cites W2057810741 @default.
W3128328166 cites W2057868964 @default.
W3128328166 cites W2061438946 @default.
W3128328166 cites W2073317560 @default.
W3128328166 cites W2090689335 @default.
W3128328166 cites W2119531181 @default.
W3128328166 cites W2159514557 @default.
W3128328166 cites W2167145078 @default.
W3128328166 cites W2198098822 @default.
W3128328166 cites W2205510492 @default.
W3128328166 cites W2466555824 @default.
W3128328166 cites W2488758040 @default.
W3128328166 cites W2510963664 @default.
W3128328166 cites W2592650851 @default.
W3128328166 cites W2594450422 @default.
W3128328166 cites W2606833567 @default.
W3128328166 cites W2610279045 @default.
W3128328166 cites W2612665982 @default.
W3128328166 cites W2625867474 @default.
W3128328166 cites W2745343410 @default.
W3128328166 cites W2750286808 @default.
W3128328166 cites W2750395192 @default.
W3128328166 cites W2761230295 @default.
W3128328166 cites W2765505702 @default.
W3128328166 cites W2766400035 @default.
W3128328166 cites W2766934255 @default.
W3128328166 cites W2774653084 @default.
W3128328166 cites W2783609002 @default.
W3128328166 cites W2789772642 @default.
W3128328166 cites W2790220600 @default.
W3128328166 cites W2790624867 @default.
W3128328166 cites W2790887126 @default.
W3128328166 cites W2799597649 @default.
W3128328166 cites W2807129545 @default.
W3128328166 cites W2884165914 @default.
W3128328166 cites W2897430944 @default.
W3128328166 cites W2899911362 @default.
W3128328166 cites W2902573949 @default.
W3128328166 cites W2936457686 @default.
W3128328166 cites W2941986503 @default.
W3128328166 cites W2945139515 @default.
W3128328166 cites W2945713203 @default.
W3128328166 cites W2953759533 @default.
W3128328166 cites W2954016944 @default.
W3128328166 cites W2971552506 @default.
W3128328166 cites W2980329246 @default.
W3128328166 cites W2982994571 @default.
W3128328166 cites W2993885754 @default.
W3128328166 cites W2995254025 @default.
W3128328166 cites W2997207075 @default.
W3128328166 cites W2998705371 @default.
W3128328166 cites W2999111270 @default.
W3128328166 cites W3007153523 @default.
W3128328166 cites W3009099635 @default.
W3128328166 cites W3012005183 @default.
W3128328166 cites W3017974589 @default.
W3128328166 cites W3025998519 @default.
W3128328166 cites W3036199571 @default.
W3128328166 cites W3040933017 @default.
W3128328166 cites W3041693259 @default.
W3128328166 cites W3042094381 @default.
W3128328166 cites W3048273311 @default.
W3128328166 cites W3080151253 @default.
W3128328166 cites W3083352469 @default.
W3128328166 cites W3097328082 @default.
W3128328166 cites W3103693542 @default.
W3128328166 cites W3111700522 @default.
W3128328166 cites W4243106509 @default.
W3128328166 doi "https://doi.org/10.3390/electronics10040447" @default.
W3128328166 hasPublicationYear "2021" @default.
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