Power networks at the distribution level are becoming more complex in their behavior and more heavily stressed due to the growth of decentralized energy sources. Demand response (DR) programs can increase the level of flexibility on the demand side by discriminating the consumption patterns of end-users from their typical profiles in response to market signals. The exploitation of artificial intelligence (AI) methods in demand response applications has attracted increasing interest. Particle swarm optimization (PSO) is a computational intelligence (CI) method that belongs to the field of AI and is widely used for resources scheduling, mainly due to its relatively low complexity and computational requirements and its ability to identify near-optimal solutions in a reasonable timeframe.
Economic benefits:
Reduction in greenhouse gas emissions:
Refs | Type of Constraints | Objective Type | Objectives |
---|---|---|---|
[16] | Egrid + Estorage + User Convenience | Single | Electricity cost minimization |
[19] | Egrid + Estorage + ERES + User Convenience |
Single with weights | Electricity cost minimization + user convenience maximization |
[20] | Thermal Comfort | Single | Energy consumption minimization |
[21] | Estorage | Single | Electricity cost minimization |
[22][53] | Estorage + User Convenience | Single | Electricity cost minimization |
[23][41][64] | User Convenience | Single with weights | Electricity cost minimization + user convenience maximization |
[24] | ERES | Multiple (Pareto) | Electricity cost minimization, distributing load across two energy sources (wind + solar) with different fitness functions |
[25] | ERES + User Convenience | Single | Electricity cost minimization |
[26] | Egrid + Estorage + ERES | Multiple (Pareto) | Electricity cost minimization + Environmental cost (emissions) minimization |
[27][30] | Egrid + Estorage + Thermal Comfort + User Convenience |
Single | Electricity cost minimization |
[28] | Egrid + ERES | Single | Electricity cost minimization |
[29] | Egrid + Estorage + User Convenience | Single (aggregated objectives) | Electricity cost minimization + PAR minimization |
[31] | Egrid + Estorage + ERES + Thermal Comfort + User Convenience |
Single | Electricity cost minimization |
[32] | Egrid + Estorage | Single | Electricity cost minimization |
[33] | Egrid + ERES | Single | Consumer profit maximization |
[34] | Thermal Comfort + User Convenience | Single | Energy consumption minimization |
[35] | Voltage levels + User Convenience | Single with penalties | Electricity cost minimization + power loss cost minimization + constraints (penalties) |
[36] | Estorage + User Convenience | Single (aggregated objectives) | Electricity cost minimization + PAR minimization |
[37] | Egrid + Estorage + ERES + Voltage levels | Single | Distribution power loss minimization |
[38] | User Convenience | Single with weights | Electricity cost minimization + discomfort index minimization |
[39] | Egrid + Estorage | Single | Utility electricity cost minimization (DA, imbalance costs, and battery cycling cost) |
[40] | Estorage | Single | Total system cost minimization (incl. investments) to optimize minigrid components |
[42] | Egrid + User Convenience | Single with weights | Electricity cost minimization + user convenience maximization |
[43] | Egrid + Estorage + Thermal Comfort + User Convenience |
Single with weights | Electricity cost minimization + user convenience maximization + grid load variance minimization (peak caused by DR actions) |
[44] | Estorage + Thermal Comfort | Single | Consumer profit maximization |
[45] | User Convenience | Multiple (bi-level) | Consumer profit maximization, after scheduling manually operated appliances with the worst impact on electricity payments |
[46] | Egrid + User Convenience | Multiple (bi-level) | Retailer profit maximization, after consumer electricity cost minimization |
[47][79] | - | Single | Electricity cost minimization |
[48] | Estorage + User Convenience | Single with weights | Electricity cost minimization + user convenience maximization |
[49] | Egrid + User Convenience | Single | Electricity cost minimization |
[50] | Estorage | Multiple (bi-level) | System cost minimization (NPC) + power shortage minimization |
[51] | Egrid + User Convenience | Single (aggregated objectives) | Electricity cost minimization + PAR minimization + user convenience maximization |
[52] | Egrid + Thermal Comfort + User Convenience |
Single | Electricity cost minimization |
[54] | Estorage + ERES | Multiple (Pareto) | Electricity cost minimization + environmental cost/emission minimization |
[55] | Estorage + Thermal Comfort | Single | Flexibility potential estimation |
[56][78] | Estorage + Thermal Comfort + User Convenience |
Single | Electricity cost minimization |
[57] | User Convenience | Multiple (Pareto) | Electricity cost minimization + load deviation minimization + user convenience maximization |
[58] | Estorage + Thermal Comfort + User Convenience |
Single with weights | Electricity cost minimization (incl. battery degradation costs) + user comfort (incl. thermal and convenience) |
[59] | Egrid + Estorage | Single with penalties | Electricity cost minimization + DR curtailment minimization + Pmax violation (penalty) |
[60] | Egrid + User Convenience | Multiple (Pareto) | Electricity cost minimization + PAR minimization + CO2 minimization |
[61] | Estorage + Thermal Comfort | Single with penalties | Electricity cost minimization + User comfort (penalties) |
[62] | User Convenience | Single with penalties | Utility electricity cost minimization for DR + consumer load interruptions (penalties) |
[63] | Egrid + Voltage levels + Estorage + User Convenience |
Single | Total system cost minimization |
[65] | Estorage + User Convenience | Single with weights | Electricity cost minimization + user convenience maximization + CO2 minimization |
[66] | Egrid | Multiple (bi-level) | DNO operational cost minimization after MG operational cost minimization |
[67][70] | User Convenience | Single | Electricity cost minimization |
[68] | Thermal Comfort | Single | Electricity cost minimization |
[69] | Estorage + Thermal Comfort + User Convenience |
Single | User comfort maximization |
[71] | Egrid + Estorage + ERES + Thermal Comfort + User Convenience |
Single (aggregated objectives) | Electricity cost minimization + PAR minimization + user convenience maximization + CO2 minimization |
[72] | Egrid + User Convenience | Single with weights | Load deviation minimization + MG profit maximization |
[73] | Egrid + Voltage levels + Estorage | Single with penalties | Total system cost minimization + network loss minimization + constraints (penalty) |
[74] | Egrid + Estorage + Thermal Comfort | Single | Electricity cost minimization |
[75] | Egrid + Estorage + Thermal Comfort | Multiple (Pareto) | System cost minimization + Environmental cost minimization |
[76] | Egrid + Estorage + Thermal Comfort + User Convenience |
Single | Energy bill (electricity and gas) minimization |
[77] | Thermal Comfort + User Convenience | Single | Electricity cost minimization |
[80] | Estorage + ERES | Single with weights | Total system cost minimization + CO2 minimization + curtailed RES minimization |
[81] | User Convenience | Single | Electricity cost minimization (per appliance cluster) |
Ref. | No. Users | Control Level | Electricity Tariffs | Energy Resources |
---|---|---|---|---|
[16][22][32] | Single | Local—Household | ToU | DG + energy storage + household appliances (excl. heating/cooling) |
[19] | Multiple | Local—Household | ToU + IBR | Heating/cooling + DG + energy storage + Household appliances (excl. heating/cooling) |
[20] | Single | Local—Household | DLC | Heating/cooling + household appliances (excl. heating/cooling) |
[21] | Multiple | Decentralized—Microgrid | RTP | DG + energy storage |
[23] | Multiple | Local—Household | RTP | Heating/cooling + household appliances (excl. heating/cooling) |
[24] | Single | Local—Household | - | Heating/cooling + DG + household appliances (excl. heating/cooling) |
[25] | Single | Local—Household | ToU | Heating/cooling + EV + DG + energy storage + Household appliances (excl. heating/cooling) |
[26][54] | Multiple | Decentralized—Microgrid | Price-offer packages (incentive-based) |
DG + energy storage |
[27][69] | Single | Local—Household | RTP | Heating/cooling + DG + energy storage + household appliances (excl. heating/cooling) |
[28] | Single | Local—Household | ToU | EV + DG + energy storage + household appliances (excl. heating/cooling) |
[29] | Multiple | Local—Household + Decentralized—Microgrid |
RTP + IBR | Heating/cooling + DG + energy storage + household appliances (excl. heating/cooling) |
[30] | Single | Local—Household | ToU | Heating/cooling + EV + DG + Household appliances (excl. Heating/cooling) |
[31][56][76] | Single | Local—Household | RTP | Heating/cooling + energy storage + household appliances (excl. heating/cooling) |
[33] | Multiple | Decentralized—Microgrid | Dynamic pricing based on RES generation | DG |
[34] | Single | Local—Household | - | Heating/cooling + household appliances (excl. heating/cooling) |
[35] | Multiple | Centralized— Utility or Aggregator |
Consumer bidding prices | Power transformers + EV + household appliances (excl. heating/cooling) |
[36][48] | Single | Local—Household | RTP + IBR | Heating/cooling + DG + energy storage + Household appliances (excl. heating/cooling) |
[37] | Multiple | Centralized— Utility or Aggregator |
- | Power transformers + DG + energy storage |
[38][51][57][68] | Single | Local—Household | ToU | Heating/cooling + household appliances (excl. heating/cooling) |
[38][51][52][57][70] | Single | Local—Household | RTP | Heating/cooling + household appliances (excl. heating/cooling) |
[39] | Multiple | Decentralized—Microgrid | - | Heating/cooling + DG + energy storage |
[40] | Multiple | Decentralized— Standalone Microgrid |
- | EV + DG + energy storage + Household appliances (excl. heating/cooling) |
[41] | Single | Local—Household | RTP + IBR | Heating/cooling + DG + household appliances (excl. heating/cooling) |
[42] | Multiple | Local—Household | CPP, RTP | Household appliances (excl. heating/cooling) |
[43] | Multiple | Decentralized—Microgrid | RTP | Heating/cooling + household appliances (excl. heating/cooling) |
[44] | Single | Local—Household | ToU, CPP | Heating/cooling + EV + DG |
[45] | Single | Local—Household | RTP + IBR | heating/cooling + household appliances (excl. heating/cooling) |
[46] | Multiple | Decentralized—Microgrid | RTP | Heating/cooling + EV + household appliances (excl. heating/cooling) |
[47][60][79] | Multiple | Centralized— Utility or Aggregator |
RTP | Household appliances (excl. heating/cooling) |
[48] | Single | Local—Household | ToU, CPP, RTP + IBR | Heating/cooling + DG + energy storage + household appliances (excl. heating/cooling) |
[49] | Single | Local—Household | RTP | Household appliances (excl. heating/cooling) |
[50] | Multiple | Decentralized— Standalone Microgrid |
- | heating/cooling + DG + energy storage + household appliances (excl. heating/cooling) |
[53][58][71] | Single | Local—Household | RTP | Heating/cooling + EV + DG + energy storage + household appliances (excl. heating/cooling) |
[55] | Single | Local—Household | - | Heating/cooling + DG + energy storage |
[59] | Multiple | Centralized— Utility or Aggregator |
ToU | Heating/cooling + DG + energy storage + household appliances (excl. heating/cooling) |
[60] | Multiple | Centralized— Utility or Aggregator |
ToU, CPP, RTP | Household appliances (excl. heating/cooling) |
[61] | Multiple | Local—Household | RTP | Heating/cooling + EV + energy storage |
[62] | Multiple | Centralized— Utility or Aggregator |
Load curtailment (incentive-based) |
Household appliances (excl. heating/cooling) |
[63] | Multiple | Centralized— Utility or Aggregator |
Trip-reducing and trip-shifting schemes (incentive-based) |
Power transformers + EV + DG |
[64] | Single | Local—Household | RTP, ToU, load curtailment (incentive-based) |
Heating/cooling + EV + household appliances (excl. heating/cooling) |
[65] | Single | Local—Household | RTP | Heating/cooling + EV + DG + household appliances (excl. heating/cooling) |
[66] | Multiple | Decentralized-—Microgrid | RTP | DG |
[67] | Single | Local—Household | ToU | Household appliances (excl. heating/cooling) |
[72] | Multiple | Decentralized—Microgrid | - | DG + Household appliances (excl. heating/cooling) |
[73] | Multiple | Decentralized—Microgrid | - | DG + energy storage + household appliances (excl. heating/cooling) |
[64][74] | Single | Local—Household | ToU | Heating/cooling + EV + household appliances (excl. heating/cooling) |
[75] | Single | Decentralized—Microgrid | RTP | Heating/cooling + DG + energy storage + household appliances (excl. heating/cooling) |
[77] | Multiple | Local—Household | RTP | Heating/cooling + DG + household appliances (excl. heating/cooling) |
[78] | Multiple | Decentralized—Microgrid | RTP | Heating/cooling + EV + DG + energy storage + household appliances (excl. heating/cooling) |
[79] | Multiple | Centralized— Utility or Aggregator |
RTP | Household appliances (excl. heating/cooling) |
[80] | Multiple | Decentralized— Standalone Microgrid |
- | DG + energy storage + household appliances (excl. heating/cooling) |
[81] | Multiple | Decentralized—Microgrid | RTP + IBR | Household appliances (excl. heating/cooling) |
This entry is adapted from the peer-reviewed paper 10.3390/en15062211