Enrico Casella, Simone Silvestri, D. A. Baker, Sajal K. Das
{"title":"基于反向拍卖理论和机器学习的以人为本的电力保护框架","authors":"Enrico Casella, Simone Silvestri, D. A. Baker, Sajal K. Das","doi":"10.1145/3656348","DOIUrl":null,"url":null,"abstract":"\n Extreme outside temperatures resulting from heat waves, winter storms, and similar weather-related events trigger the Heating Ventilation and Air Conditioning (HVAC) systems, resulting in challenging, and potentially catastrophic, peak loads. As a consequence, such extreme outside temperatures put a strain on power grids and may thus lead to blackouts. In order to avoid the financial and personal repercussions of peak loads, demand response and power conservation represent promising solutions. Despite numerous efforts, it has been shown that the current state-of-the-art fails to consider: i) the complexity of human behavior when interacting with power conservation systems; and ii) realistic home-level power dynamics. As a consequence, this leads to approaches that are i) ineffective due to poor long-term user engagement; and ii) too abstract to be used in real-world settings. In this paper, we propose an auction-theory-based power conservation framework for HVAC designed to address such individual human component through a three-fold approach:\n personalized preferences\n of power conservation,\n models of realistic user behavior\n , and\n realistic home-level power dynamics\n . In our framework, the System Operator (SO) sends Load Serving Entities (LSEs) the required power saving to tackle peak loads at the residential distribution feeder. Each LSE then prompts its users to provide\n bids\n , i.e.,\n personalized preferences\n of thermostat temperature adjustments, along with corresponding financial compensations. We employ\n models of realistic user behavior\n by means of online surveys to gather user bids and evaluate user interaction with such system.\n Realistic home-level power dynamics\n are implemented by our machine-learning-based Power Saving Predictions (PSP) algorithm, calculating the individual power savings in each user’s home resulting from such bids. A machine-learning-based Power Saving Predictions (PSP) algorithm is executed by the users’ Smart Energy Management System (SEMS). PSP translates temperature adjustments into the corresponding power savings. Then, the SEMS sends bids back to the LSE, which selects the auction winners through an optimization problem called POwer Conservation Optimization (POCO). We prove that POCO is NP-hard, and thus provide two approaches to solve this problem. One approach is an optimal pseudo-polynomial algorithm called DYnamic programming Power Saving (DYPS), while the second is a heuristic polynomial-time algorithm called Greedy Ranking Allocation (GRAN). EnergyPlus, the high-fidelity and gold-standard energy simulator funded by the U.S. Department of Energy, was used to validate our experiments, as well as to collect data to train PSP. We further evaluate the results of the auctions across several scenarios, showing that, as expected, DYPS finds the optimal solution, while GRAN outperforms recent state-of-the-art approaches.\n","PeriodicalId":7055,"journal":{"name":"ACM Transactions on Cyber-Physical Systems","volume":null,"pages":null},"PeriodicalIF":2.0000,"publicationDate":"2024-04-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"A Human-Centered Power Conservation Framework based on Reverse Auction Theory and Machine Learning\",\"authors\":\"Enrico Casella, Simone Silvestri, D. A. Baker, Sajal K. Das\",\"doi\":\"10.1145/3656348\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"\\n Extreme outside temperatures resulting from heat waves, winter storms, and similar weather-related events trigger the Heating Ventilation and Air Conditioning (HVAC) systems, resulting in challenging, and potentially catastrophic, peak loads. As a consequence, such extreme outside temperatures put a strain on power grids and may thus lead to blackouts. In order to avoid the financial and personal repercussions of peak loads, demand response and power conservation represent promising solutions. Despite numerous efforts, it has been shown that the current state-of-the-art fails to consider: i) the complexity of human behavior when interacting with power conservation systems; and ii) realistic home-level power dynamics. As a consequence, this leads to approaches that are i) ineffective due to poor long-term user engagement; and ii) too abstract to be used in real-world settings. In this paper, we propose an auction-theory-based power conservation framework for HVAC designed to address such individual human component through a three-fold approach:\\n personalized preferences\\n of power conservation,\\n models of realistic user behavior\\n , and\\n realistic home-level power dynamics\\n . In our framework, the System Operator (SO) sends Load Serving Entities (LSEs) the required power saving to tackle peak loads at the residential distribution feeder. Each LSE then prompts its users to provide\\n bids\\n , i.e.,\\n personalized preferences\\n of thermostat temperature adjustments, along with corresponding financial compensations. We employ\\n models of realistic user behavior\\n by means of online surveys to gather user bids and evaluate user interaction with such system.\\n Realistic home-level power dynamics\\n are implemented by our machine-learning-based Power Saving Predictions (PSP) algorithm, calculating the individual power savings in each user’s home resulting from such bids. A machine-learning-based Power Saving Predictions (PSP) algorithm is executed by the users’ Smart Energy Management System (SEMS). PSP translates temperature adjustments into the corresponding power savings. Then, the SEMS sends bids back to the LSE, which selects the auction winners through an optimization problem called POwer Conservation Optimization (POCO). We prove that POCO is NP-hard, and thus provide two approaches to solve this problem. One approach is an optimal pseudo-polynomial algorithm called DYnamic programming Power Saving (DYPS), while the second is a heuristic polynomial-time algorithm called Greedy Ranking Allocation (GRAN). EnergyPlus, the high-fidelity and gold-standard energy simulator funded by the U.S. Department of Energy, was used to validate our experiments, as well as to collect data to train PSP. 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引用次数: 0
摘要
热浪、冬季风暴和类似天气事件导致的极端室外温度会触发暖通空调(HVAC)系统,从而产生具有挑战性的、可能是灾难性的峰值负荷。因此,这种极端的室外温度会对电网造成压力,从而可能导致停电。为了避免高峰负荷对经济和个人造成的影响,需求响应和节约用电是很有前途的解决方案。尽管做出了许多努力,但事实证明,当前的先进技术未能考虑到:i) 人类与节电系统互动时行为的复杂性;ii) 现实的家庭电力动态。因此,这导致了以下问题:i) 由于用户长期参与度不高而无效;ii) 过于抽象,无法在现实环境中使用。在本文中,我们提出了一个基于拍卖理论的暖通空调节电框架,旨在通过三方面的方法来解决这种个人人为因素:个性化的节电偏好、现实的用户行为模型和现实的家庭电力动态。在我们的框架中,系统运营商(SO)向负载服务实体(LSE)发送所需的节电信息,以解决住宅配电馈线的峰值负载问题。然后,每个 LSE 提示其用户提供出价,即恒温器温度调节的个性化偏好,以及相应的经济补偿。我们通过在线调查采用现实用户行为模型来收集用户出价,并评估用户与该系统的互动情况。我们基于机器学习的节电预测(PSP)算法实现了真实的家庭级电力动态,计算出每个用户家庭因这些出价而节省的电量。基于机器学习的节电预测 (PSP) 算法由用户的智能能源管理系统 (SEMS) 执行。PSP 将温度调整转化为相应的节电效果。然后,SEMS 将出价反馈给 LSE,LSE 通过一个名为 POwer Conservation Optimization (POCO) 的优化问题选出拍卖获胜者。我们证明了 POCO 的 NP 难度,因此提供了两种解决该问题的方法。一种方法是最优伪多项式算法,称为动态编程节电(DYPS);另一种方法是启发式多项式时间算法,称为贪婪排序分配(GRAN)。EnergyPlus 是由美国能源部资助的高保真黄金标准能源模拟器,用于验证我们的实验,并收集数据以训练 PSP。我们进一步评估了几种情况下的拍卖结果,结果表明,正如预期的那样,DYPS 找到了最优解,而 GRAN 则优于最近最先进的方法。
A Human-Centered Power Conservation Framework based on Reverse Auction Theory and Machine Learning
Extreme outside temperatures resulting from heat waves, winter storms, and similar weather-related events trigger the Heating Ventilation and Air Conditioning (HVAC) systems, resulting in challenging, and potentially catastrophic, peak loads. As a consequence, such extreme outside temperatures put a strain on power grids and may thus lead to blackouts. In order to avoid the financial and personal repercussions of peak loads, demand response and power conservation represent promising solutions. Despite numerous efforts, it has been shown that the current state-of-the-art fails to consider: i) the complexity of human behavior when interacting with power conservation systems; and ii) realistic home-level power dynamics. As a consequence, this leads to approaches that are i) ineffective due to poor long-term user engagement; and ii) too abstract to be used in real-world settings. In this paper, we propose an auction-theory-based power conservation framework for HVAC designed to address such individual human component through a three-fold approach:
personalized preferences
of power conservation,
models of realistic user behavior
, and
realistic home-level power dynamics
. In our framework, the System Operator (SO) sends Load Serving Entities (LSEs) the required power saving to tackle peak loads at the residential distribution feeder. Each LSE then prompts its users to provide
bids
, i.e.,
personalized preferences
of thermostat temperature adjustments, along with corresponding financial compensations. We employ
models of realistic user behavior
by means of online surveys to gather user bids and evaluate user interaction with such system.
Realistic home-level power dynamics
are implemented by our machine-learning-based Power Saving Predictions (PSP) algorithm, calculating the individual power savings in each user’s home resulting from such bids. A machine-learning-based Power Saving Predictions (PSP) algorithm is executed by the users’ Smart Energy Management System (SEMS). PSP translates temperature adjustments into the corresponding power savings. Then, the SEMS sends bids back to the LSE, which selects the auction winners through an optimization problem called POwer Conservation Optimization (POCO). We prove that POCO is NP-hard, and thus provide two approaches to solve this problem. One approach is an optimal pseudo-polynomial algorithm called DYnamic programming Power Saving (DYPS), while the second is a heuristic polynomial-time algorithm called Greedy Ranking Allocation (GRAN). EnergyPlus, the high-fidelity and gold-standard energy simulator funded by the U.S. Department of Energy, was used to validate our experiments, as well as to collect data to train PSP. We further evaluate the results of the auctions across several scenarios, showing that, as expected, DYPS finds the optimal solution, while GRAN outperforms recent state-of-the-art approaches.