Stochastic optimization for retailers with distributed wind generation considering demand response

Golmohamadi, Hessam; Keypour, Reza

doi:10.1007/s40565-017-0368-y

Cited by 36 publications

(21 citation statements)

References 43 publications

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“…In [20], the problem of dynamic pricing for DRM is formulated as a Markov decision process, and reinforcement learning is used to solve it. In [21], demand response is modeled by directly quantifying the delay-tolerant demand and its dependence on price by linear, potential, exponential and logarithmic load functions.…”

Section: Related Problems In Energy Management and Drmmentioning

confidence: 99%

Bilevel programming approach to demand response management with day-ahead tariff

Kovács

2019

J. Mod. Power Syst. Clean Energy

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This paper introduces a bilevel programming approach to electricity tariff optimization for the purpose of demand response management (DRM) in smart grids. In the multi-follower Stackelberg game model, the leader is the profit-maximizing electricity retailer, who must set a time-of-use variable energy tariff in the grid. Followers correspond to groups of prosumers (simultaneous producers and consumers of the electricity. They response to the observed tariff, schedule controllable loads and determine the charging/discharging policy of their batteries to minimize the cost of electricity and to maximize the utility at the same time. A bilevel programming formulation of the problem is defined, and its fundamental properties are proven. The primal-dual reformulation is proposed in this paper to convert the bilevel optimization problem into a single-level quadratically constrained quadratic program (QCQP), and a successive linear programming (SLP) algorithm is applied to solve it. It is demonstrated in computational experiments that the proposed approach outperforms typical earlier methods based on the Karush-Kuhn-Tucker (KKT) reformulation regarding both solution quality and computational efficiency on practically relevant problem sizes. Besides, it also offers more flexible modeling capabilities.

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Section: Related Problems In Energy Management and Drmmentioning

confidence: 99%

Bilevel programming approach to demand response management with day-ahead tariff

Kovács

2019

J. Mod. Power Syst. Clean Energy

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“…Objective (27) is maximized subject to constraints on bilateral contract (3), self-generating (4) to (17), spot market (19), energy balance (20), sale price (22) to (24), and demand redistribution constraint (25). Here, sale price, price-responsive demand, and portfolio of energy to be procured from various options are key decision variables of the problem.…”

Section: Objective Functionmentioning

confidence: 99%

“…A retailer with RE self-generation makes decisions targeting best utilization of RE availability, to maximize its profit. 24 The presence of multiple RE sources such as wind and solar would impact the optimal trading strategy of the retailer 25,26 than with a single RE source. In this perspective, this paper determines optimal Time of Use (ToU) sale prices to be offered and optimal energy procurement portfolio, for a retailer with and without RE, considering elastic demand and wholesale market price uncertainty, aiming to maximize retailer's profit.…”

mentioning

confidence: 99%

“…This exposes retailers to price risk, which needs to be considered while making procurement decisions. 24 The presence of multiple RE sources such as wind and solar would impact the optimal trading strategy of the retailer 25,26 than with a single RE source. 9,10 Further, demand shifting over different hours significantly impacts its energy procurement cost, price risk, and eventually the offered sale price.…”

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confidence: 99%

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Risk‐based retailer profit maximization: Time of Use price setting for elastic demand

Chawda

Mathuria

Bhakar

2019

Int Trans Electr Energ Syst

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Summary Retailers in electricity markets face challenges of hourly varying energy prices and consumers' elastic demand. Besides these challenges, utilization of high renewable energy (RE) self‐generation such as solar energy could significantly affect energy procurement and sale prices decisions of a retailer. A retailer with RE self‐generation makes decisions targeting best utilization of RE availability, to maximize its profit. However, a retailer without RE makes decisions considering energy prices and elastic demand. In this perspective, this paper determines optimal Time of Use (ToU) sale prices to be offered and optimal energy procurement portfolio, for a retailer with and without RE, considering elastic demand and wholesale market price uncertainty, aiming to maximize retailer's profit. Case study considers three consumer classes to examine risk neutral and risk averse behavior of a retailer. Results illustrate impact of multiple consumer class behavior on ToU price, procurement strategy, and risk preferences of a retailer.

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“…Moreover, the DSO could make concession on its current profit to achieve the optimal longterm development plan. This approach is significantly superior to the previous studies focusing on the interests of consumers [29,30] or the profits of retailers [31], as those studies could not avoid falling into sub-optimum due to the short-sightedness of consumers/retailers.…”

Section: Introductionmentioning

confidence: 98%

Distributed generation planning for diversified participants in demand response to promote renewable energy integration

Dang

Wang

Shao

et al. 2019

J. Mod. Power Syst. Clean Energy

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In modern distribution system, the distribution system operator (DSO) acts as a market facilitator and data manager as well as an energy supplier and operation controller. In this circumstance, the DSO should comprehensively consider the diversified participants of the modern distribution system when making investment decisions of distributed generation (DG). This paper proposes a DG planning model considering the behavior of the diversified participants, which are motivated to cooperate with distributed renewable energy resources to promote their integration, and to achieve the optimal DG investment plan. The optimization model takes a centralized structure but fully considers the preferences, profits and comfort levels of the aggregators and consumers. The model is linearized into a mixed-integer linear programming (MILP) problem and is solved by CPLEX. Results of the case study show that when the DSO spares subsidies to the aggregators and consumers to encourage their participation in demand response (DR) programs, it earns more compared with providing no subsidies for DR participation. It is also demonstrated that the overall profit increases as the subsidies increase within a certain range, but decreases when the subsidies exceed this range. Therefore, the DSO needs to carefully choose the subsidization level to achieve the optimal utilization of renewable energy and demand flexibility. The optimal subsidization level is derived from the model proposed in this paper. Therefore, this paper puts forward a new pattern to utilize the distributed renewable energy sources, and provides guidance in policy making and DR program implementation.

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Stochastic optimization for retailers with distributed wind generation considering demand response

Cited by 36 publications

References 43 publications

Bilevel programming approach to demand response management with day-ahead tariff

Bilevel programming approach to demand response management with day-ahead tariff

Risk‐based retailer profit maximization: Time of Use price setting for elastic demand

Distributed generation planning for diversified participants in demand response to promote renewable energy integration

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