A comprehensive review on energy saving options and saving potential in low voltage electricity distribution networks: Building and public lighting
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Mehdi Abapour | Amjad Anvari-Moghaddam | Jeng Shiun Lim | Fausto Pedro García Márquez | Behnam Mohammadi-Ivatloo | Arash Moradzadeh | Omid Sadeghian | B. Mohammadi-ivatloo | A. Anvari‐Moghaddam | J. Lim | Arash Moradzadeh | F. Márquez | Omid Sadeghian | M. Abapour
[1] Mariagrazia Dotoli,et al. An optimization tool for energy efficiency of street lighting systems in smart cities , 2017 .
[2] Felix Felgner,et al. FV-battery-diesel microgrid design for buildings subject to severe power outages , 2017, 2017 IEEE PES PowerAfrica.
[3] Maurice Gagnaire,et al. Improving energy distribution for EV charging over public lighting systems , 2014, 2014 International Conference on Connected Vehicles and Expo (ICCVE).
[4] Amanda Lange Salvia,et al. An analysis of the applications of Analytic Hierarchy Process (AHP) for selection of energy efficiency practices in public lighting in a sample of Brazilian cities , 2019, Energy Policy.
[5] Kari Alanne,et al. Approaching net zero energy housing through integrated EV , 2018 .
[6] Mattia De Rosa,et al. Mapping the energy flexibility potential of single buildings equipped with optimally-controlled heat pump, gas boilers and thermal storage , 2019, Sustainable Cities and Society.
[7] Ke Li,et al. Dynamic modeling of potentially conflicting energy reduction strategies for residential structures in semi-arid climates. , 2012, Journal of environmental management.
[8] Energy-saving analysis of air source heat pump integrated with a water storage tank for heating applications , 2020 .
[9] V. Tyagi,et al. Integration of passive PCM technologies for net-zero energy buildings , 2018, Sustainable Cities and Society.
[10] Luis Pérez-Lombard,et al. A review on buildings energy consumption information , 2008 .
[11] K. F. Fong,et al. Investigation on zero grid-electricity design strategies of solid oxide fuel cell trigeneration system for high-rise building in hot and humid climate , 2014 .
[12] Furkan Dincer,et al. Optimal design of hybrid PV-Diesel-Battery systems for isolated lands: A case study for Kilis, Turkey , 2017 .
[13] Chenli Wang,et al. Energy saving impact of occupancy-driven thermostat for residential buildings , 2020 .
[14] G. Casa,et al. A new way to manage public lighting , 1999 .
[15] Ambrose Dodoo,et al. Effects of heat and electricity saving measures in district-heated multistory residential buildings , 2014 .
[16] K. Lai,et al. Promoting sustainability of manufacturing industry through the lean energy-saving and emission-reduction strategy. , 2019, The Science of the total environment.
[17] M. Bah,et al. Quantifying the impacts of energy price reform on living expenses in Saudi Arabia , 2020 .
[18] V. Di Dio,et al. Energy saving and user satisfaction for a new advanced public lighting system , 2019, Energy Conversion and Management.
[19] M. Farid,et al. Application of an Active PCM Storage System into a Building for Heating/Cooling Load Reduction , 2020, Thermal Energy Storage with Phase Change Materials.
[20] Mike B. Roberts,et al. Impact of shared battery energy storage systems on photovoltaic self-consumption and electricity bills in apartment buildings , 2019, Applied Energy.
[21] Kim Bjarne Wittchen,et al. Estimating the energy-saving potential in national building stocks – A methodology review , 2018 .
[22] A. Ngaopitakkul,et al. Feasibility Study and Impact of Daylight on Illumination Control for Energy-Saving Lighting Systems , 2018, Sustainability.
[23] Pedro Núñez-Cacho Utrilla,et al. The Use of Led Technology and Biomass to Power Public Lighting in a Local Context: The Case of Baeza (Spain) , 2018, Energies.
[24] H. Mehrjerdi. Peer-to-peer home energy management incorporating hydrogen storage system and solar generating units , 2020 .
[25] L. Doulos,et al. The effect of the continuous energy efficient upgrading of LED street lighting technology: The case study of Egnatia Odos , 2019, 2019 Second Balkan Junior Conference on Lighting (Balkan Light Junior).
[26] Behnam Mohammadi-Ivatloo,et al. Optimal chiller loading for saving energy by exchange market algorithm , 2018, Energy and Buildings.
[27] I. Vassileva,et al. Active buildings in smart grids—Exploring the views of the Swedish energy and buildings sectors , 2016 .
[28] M. Akbari,et al. Potential of solar energy in developing countries for reducing energy-related emissions , 2018, Renewable and Sustainable Energy Reviews.
[29] Tarja Häkkinen,et al. User engaging practices for energy saving in buildings: Critical review and new enhanced procedure , 2017 .
[30] A. Djuretic,et al. Actual energy savings when replacing high-pressure sodium with LED luminaires in street lighting , 2018, Energy.
[31] Mariagrazia Dotoli,et al. A Multi-Period Approach for the Optimal Energy Retrofit Planning of Street Lighting Systems , 2019, Applied Sciences.
[32] Benoit Robyns,et al. Fuzzy logic based energy management strategy for commercial buildings integrating photovoltaic and storage systems , 2012 .
[33] Hemanshu R. Pota,et al. Energy management for a commercial building microgrid with stationary and mobile battery storage , 2016 .
[34] Satu Paiho,et al. Life-cycle cost analyses of heat pump concepts for Finnish new nearly zero energy residential buildings , 2017 .
[35] John Psarras,et al. An integrated system for buildings’ energy-efficient automation: Application in the tertiary sector , 2013 .
[36] Yun Seng Lim,et al. Methodology for assessing viability of energy storage system for buildings , 2016 .
[37] Wayes Tushar,et al. Energy Management Strategy for Zone Cooling Load Demand Reduction in Commercial Buildings: A Data-Driven Approach , 2019, IEEE Transactions on Industry Applications.
[38] Daniel Gómez-Lorente,et al. A simple and accurate model for the design of public lighting with energy efficiency functions based on regression analysis , 2016 .
[39] Christian Thiel,et al. Evaluation of Several Measures to Improve the Energy Efficiency and CO2 Emission in the European Single-family houses , 2012 .
[40] W. Pan,et al. A ‘demand-supply-regulation-institution’ stakeholder partnership model of delivering zero carbon buildings , 2020 .
[41] Xi Chen,et al. Energy storage and management system design optimization for a photovoltaic integrated low-energy building , 2020 .
[42] F. Johnsson,et al. Impacts of demand response from buildings and centralized thermal energy storage on district heating systems , 2021 .
[43] Arindam Dutta,et al. Reducing cooling load of buildings in the tropical climate through window glazing: A model to model comparison , 2018 .
[44] Servando Álvarez Domínguez,et al. Analysis of the economic feasibility and reduction of a building’s energy consumption and emissions when integrating hybrid solar thermal/PV/micro-CHP systems , 2016 .
[45] Rahman Saidur,et al. Energy consumption, energy savings, and emission analysis in Malaysian office buildings , 2009 .
[46] Edris Pouresmaeil,et al. A two stage hierarchical control approach for the optimal energy management in commercial building microgrids based on local wind power and PEVs , 2018, Sustainable Cities and Society.
[47] Marc Medrano,et al. Integration of distributed generation systems into generic types of commercial buildings in California , 2008 .
[48] Poria Fajri,et al. Optimal management of residential energy storage systems in presence of intermittencies , 2020 .
[49] Ana Tejero-González,et al. Energy Analysis at a Near Zero Energy Building. A Case-Study in Spain , 2018 .
[50] Morteza Nazari-Heris,et al. Hourly Price-Based Demand Response for Optimal Scheduling of Integrated Gas and Power Networks Considering Compressed Air Energy Storage , 2020 .
[51] G. Vanoli,et al. Numerical analysis of phase change materials for optimizing the energy balance of a nearly zero energy building , 2020, Sustainable Cities and Society.
[52] Mahdi Shahbakhti,et al. Building-to-grid predictive power flow control for demand response and demand flexibility programs , 2017 .
[53] C. Ghenai,et al. Analysis of cooling load on commercial building in UAE climate using building integrated photovoltaic façade system , 2020 .
[54] Francesco Calise,et al. Detailed Modelling of the Deep Decarbonisation Scenarios with Demand Response Technologies in the Heating and Cooling Sector: A Case Study for Italy , 2017 .
[55] Min Hee Chung,et al. Potential opportunities for energy conservation in existing buildings on university campus: A field survey in Korea , 2014 .
[56] Ciprian Cristea,et al. A multi-criteria decision making approach for public lighting system selection , 2018 .
[57] Javier Bajo,et al. Intelligent system for lighting control in smart cities , 2016, Inf. Sci..
[58] Rehan Sadiq,et al. Improving the energy efficiency of the existing building stock: A critical review of commercial and institutional buildings , 2016 .
[59] S. Shaahid. Techno-economics of off-grid hybrid wind-diesel power systems for electrification of residential buildings of Yanbu - a potential industrial location of Saudi Arabia , 2018 .
[60] Gaetano Zizzo,et al. Smart city and public lighting , 2015, 2015 IEEE 15th International Conference on Environment and Electrical Engineering (EEEIC).
[61] Gianni Pasolini,et al. Design, Deployment and Evolution of Heterogeneous Smart Public Lighting Systems , 2019, Applied Sciences.
[62] J. Zamorano,et al. Statistical modelling and satellite monitoring to evaluate the upward light emissions of public lighting systems , 2015 .
[63] Haorong Li,et al. Analysis of thermal energy saving potentials through adjusting user behavior in hotel buildings of the Yangtze River region , 2019, Sustainable Cities and Society.
[64] Claudio Rossi,et al. AURORA: an Energy Efficient Public Lighting IoT System for Smart Cities , 2016, PERV.
[65] Wolf Fichtner,et al. Energy autonomy in residential buildings: a techno-economic model-based analysis of the scale effects , 2017 .
[66] Anthony Paul Roskilly,et al. Office building cooling load reduction using thermal analysis method – A case study , 2017 .
[67] Shin'ya Obara,et al. Theoretical analysis of performance of a micro gas turbine co/trigeneration system for residential buildings in a tropical region , 2013 .
[68] Gevork B. Gharehpetian,et al. Chance-constrained models for transactive energy management of interconnected microgrid clusters , 2020 .
[69] Rahman Saidur,et al. Energetic, economic and environmental benefits of utilizing the ice thermal storage systems for office building applications , 2012 .
[70] Jorge E. Gonzalez,et al. On the assessment of alternatives for building cooling load reductions for a tropical coastal city , 2019, Energy and Buildings.
[71] Petr Zak,et al. Conception of public lighting , 2016, 2016 IEEE Lighting Conference of the Visegrad Countries (Lumen V4).
[72] Giuseppina Ciulla,et al. Improvement of energy efficiency and quality of street lighting in South Italy as an action of Sustainable Energy Action Plans. The case study of Comiso (RG) , 2015 .
[73] Jack Brouwer,et al. Economic analysis of fuel cell installations at commercial buildings including regional pricing and complementary technologies , 2016 .
[74] V. Franzitta,et al. Improving energy efficiency of commercial buildings by Combined Heat Cooling and Power plants , 2020 .
[75] Nurdan Yildirim,et al. Evaluation of a hybrid system for a nearly zero energy greenhouse , 2017 .
[76] Shiming Deng,et al. Challenges in, and the development of, building energy saving techniques, illustrated with the example of an air source heat pump , 2019, Thermal Science and Engineering Progress.
[77] L. Doulos,et al. Minimizing energy consumption for artificial lighting in a typical classroom of a Hellenic public school aiming for near Zero Energy Building using LED DC luminaires and daylight harvesting systems , 2019, Energy and Buildings.
[78] J. Zhan,et al. Life cycle energy consumption and greenhouse gas emissions of urban residential buildings in Guangzhou city , 2018, Journal of Cleaner Production.
[79] Alexandros Arsalis,et al. A Decentralized, Hybrid Photovoltaic-Solid Oxide Fuel Cell System for Application to a Commercial Building , 2018, Energies.
[80] Xiao-Zhi Gao,et al. Artificial Neural Network based Smart and Energy Efficient Street Lighting System: A Case Study for Residential area in Hosur , 2019, Sustainable Cities and Society.
[81] A. Thongtha,et al. Experimental Investigation of Natural Lighting Systems Using Cylindrical Glass for Energy Saving in Buildings , 2020 .
[82] Bernardino Benito,et al. Determinants of efficiency improvement in the Spanish public lighting sector , 2020 .
[83] Saad Ladide,et al. Hybrid Renewable Power Supply for Typical Public Facilities in Six Various Climate Zones in Morocco , 2019, International Journal of Renewable Energy Research.
[84] Wenming Yang,et al. Integrating renewable energy technologies to support building trigeneration – A multi-criteria analysis , 2012 .
[85] Delia D’Agostino,et al. What is a Nearly zero energy building? Overview, implementation and comparison of definitions , 2019, Journal of Building Engineering.
[86] M. C. Bozchalui,et al. Analysis of Electric Vehicles as Mobile Energy Storage in commercial buildings: Economic and environmental impacts , 2012, 2012 IEEE Power and Energy Society General Meeting.
[87] Iakovos Michailidis,et al. Occupancy-based demand response and thermal comfort optimization in microgrids with renewable energy sources and energy storage , 2016 .
[88] Seunghoon Jung,et al. An optimal scheduling model of an energy storage system with a photovoltaic system in residential buildings considering the economic and environmental aspects , 2020 .
[89] Daniele Vitali,et al. Experimental study on a Savonius wind rotor for street lighting systems , 2016 .
[90] Thomas Kunz,et al. Peer-to-peer energy trading among smart homes , 2019, Applied Energy.
[91] Farkhondeh Jabari,et al. Design, worst case study, and sensitivity analysis of a net-zero energy building for sustainable urban development , 2020 .
[92] Khairul Salleh Mohamed Sahari,et al. Evaluation of energy-saving potential for optimal time response of HVAC control system in smart buildings , 2020 .
[93] Alexandra M. Newman,et al. Establishing conditions for the economic viability of fuel cell-based, combined heat and power distributed generation systems , 2013 .
[94] Rune Hylsberg Jacobsen,et al. Demand response potential of ventilation systems in residential buildings , 2016 .
[95] Arman Oshnoei,et al. Robust Control Scheme for Distributed Battery Energy Storage Systems in Load Frequency Control , 2020, IEEE Transactions on Power Systems.
[96] Tom van de Voort,et al. The energy saving potential of occupancy-based lighting control strategies in open-plan offices: The influence of occupancy patterns , 2017 .
[97] Shengwei Wang,et al. A power limiting control strategy based on adaptive utility function for fast demand response of buildings in smart grids , 2016 .
[98] E. Zanchini,et al. Energy saving obtainable by applying a commercially available M-cycle evaporative cooling system to the air conditioning of an office building in North Italy , 2019, Energy.
[99] Fernando J. Nogueira,et al. Street lighting LED luminaires replacing high pressure sodium lamps: Study of case , 2014, 2014 11th IEEE/IAS International Conference on Industry Applications.
[100] Tarik Kousksou,et al. Energy consumption and efficiency in buildings: current status and future trends , 2015 .
[101] Mario Andrés Paredes-Valverde,et al. IntelliHome: An internet of things‐based system for electrical energy saving in smart home environment , 2019, Comput. Intell..
[102] R. Bokel,et al. Natural summer ventilation strategies for energy-saving in high-rise buildings: a case study in the Netherlands , 2019, International Journal of Ventilation.
[103] Xiaodong Cao,et al. Building energy-consumption status worldwide and the state-of-the-art technologies for zero-energy buildings during the past decade , 2016 .
[104] Mansoor Ahmed Soomro,et al. Analyzing the Impacts of Wind Generation on Distribution System Performance , 2016 .
[105] Mehdi Abapour,et al. A novel economic structure to improve the energy label in smart residential buildings under energy efficiency programs , 2020 .
[106] Bahram Moshfegh,et al. Investigation of energy performance of newly built low-energy buildings in Sweden , 2011 .
[107] Julia Meng Pei Chen,et al. Economic analysis of a solid oxide fuel cell cogeneration/trigeneration system for hotels in Hong Kong , 2014 .
[108] Morteza Nazari-Heris,et al. Optimal Robust Scheduling of Renewable Energy-Based Smart Homes Using Information-Gap Decision Theory (IGDT) , 2019 .
[109] J. Villar,et al. Distributed energy generation in smart cities , 2013, 2013 International Conference on Renewable Energy Research and Applications (ICRERA).
[110] F. Sánchez Sutil,et al. Smart Public Lighting Control and Measurement System Using LoRa Network , 2020 .
[111] Agis M. Papadopoulos,et al. Hybrid energy fuel cell based system for household applications in a Mediterranean climate , 2015 .
[112] Soroush Oshnoei,et al. Automatic Generation Control Incorporating Electric Vehicles , 2019, Electric Power Components and Systems.
[113] Rossano Scoccia,et al. Energy saving potentials of a photovoltaic assisted heat pump for hybrid building heating system via optimal control , 2020 .
[114] Robert G. Pratt,et al. Transactive Control of Commercial Buildings for Demand Response , 2017, IEEE Transactions on Power Systems.
[115] Zita Vale,et al. A Short Review on Smart Building Energy Resource Optimization , 2019, 2019 IEEE PES GTD Grand International Conference and Exposition Asia (GTD Asia).
[116] P. Salagnac,et al. Micro-combined heat and power systems (micro-CHP) based on renewable energy sources , 2017 .
[117] Pierluigi Siano,et al. A Survey and Evaluation of the Potentials of Distributed Ledger Technology for Peer-to-Peer Transactive Energy Exchanges in Local Energy Markets , 2019, IEEE Systems Journal.
[118] Kamel Ghali,et al. Strategies for reducing energy consumption in existing office buildings , 2013 .
[119] S. Gorgulu,et al. An energy saving potential analysis of lighting retrofit scenarios in outdoor lighting systems: A case study for a university campus , 2020 .
[120] Sung-Yeul Park,et al. Cost effective BESS design for building power systems , 2013, 2013 Twenty-Eighth Annual IEEE Applied Power Electronics Conference and Exposition (APEC).
[121] Tariq Samad,et al. Automated Demand Response for Smart Buildings and Microgrids: The State of the Practice and Research Challenges , 2016, Proceedings of the IEEE.
[122] Federico Viani,et al. Experimental validation of a wireless distributed system for smart public lighting management , 2016, 2016 IEEE International Smart Cities Conference (ISC2).
[123] Mohammad Monfared,et al. Practical evaluation of an effective intelligent central dimming strategy applied to public lighting network , 2017, 2017 Conference on Electrical Power Distribution Networks Conference (EPDC).
[124] B. Mohammadi-ivatloo,et al. Transactive energy in future smart homes , 2019, The Energy Internet.
[125] A. A. Baloch,et al. Towards modern sustainable cities: Review of sustainability principles and trends , 2019, Journal of Cleaner Production.
[126] Teuku Meurah Indra Mahlia,et al. Techno-economic analysis of an optimized photovoltaic and diesel generator hybrid power system for remote houses in a tropical climate. , 2013 .
[127] Alfonso Gago-Calderón,et al. Power Quality and Energy Efficiency in the Pre-Evaluation of an Outdoor Lighting Renewal with Light-Emitting Diode Technology: Experimental Study and Amortization Analysis , 2017 .
[128] Michal Kolcun,et al. Design and simulation of hybrid system for public lighting power supply , 2016, 2016 17th International Scientific Conference on Electric Power Engineering (EPE).
[129] Branislav M. Todorović,et al. Road lighting energy-saving system based on wireless sensor network , 2017 .
[130] Genku Kayo,et al. Energy sharing and matching in different combinations of buildings, CHP capacities and operation strategy , 2014 .
[131] Mariagrazia Dotoli,et al. A decision-making tool for energy efficiency optimization of street lighting , 2017, Comput. Oper. Res..
[132] S. M. Shaahid,et al. Economic analysis of hybrid photovoltaic–diesel–battery power systems for residential loads in hot regions—A step to clean future , 2008 .
[133] Xiaonan Wang,et al. Long-term economic planning of combined cooling heating and power systems considering energy storage and demand response , 2020 .
[134] A. Immanuel Selvakumar,et al. Optimal sizing of photovoltaic/battery/diesel based hybrid system and optimal tilting of solar array using the artificial intelligence for remote houses in India , 2015 .
[135] M Martell,et al. Multiobjective control architecture to estimate optimal set points for user comfort and energy saving in buildings. , 2020, ISA transactions.
[136] Ana Castillo-Martinez,et al. A review of energy efficiency label of street lighting systems , 2017 .
[137] Henrique A. C. Braga,et al. Economic analysis of a controllable device with smart grid features applied to LED street lighting system , 2015, 2015 IEEE 24th International Symposium on Industrial Electronics (ISIE).
[138] Rachel Dzombak,et al. Exploring Cost and Environmental Implications of Optimal Technology Management Strategies in the Street Lighting Industry , 2020 .
[139] Dasheng Lee,et al. Artificial intelligence implementation framework development for building energy saving , 2020, International Journal of Energy Research.
[140] Hoseong Lee,et al. Multi-criteria evaluation of medium-sized residential building with micro-CHP system in South Korea , 2019, Energy and Buildings.
[141] A. Kosonen,et al. Zero-energy log house – Future concept for an energy efficient building in the Nordic conditions , 2020 .
[142] E. Caamaño-Martín,et al. Energy saving potential of semi-transparent photovoltaic elements for building integration , 2014 .
[143] Eike Musall,et al. Zero Energy Building A review of definitions and calculation methodologies , 2011 .
[144] L. Čuček,et al. An ecological feasibility study for developing sustainable street lighting system , 2018 .
[145] Vijay K. Sood,et al. Analysis of PV Systems and Charging Stations Integration into the Public Lighting Infrastructure , 2019, 2019 IEEE PES Innovative Smart Grid Technologies Europe (ISGT-Europe).
[146] V. Franzitta,et al. Investigating energy saving potential in a big shopping center through ventilation control , 2019, Sustainable Cities and Society.
[147] Masud Behnia,et al. A methodology to compare the economic feasibility of fuel cell‐, gas turbine‐ and microturbine‐based combined heat and power systems , 2016 .
[148] A. Rasheed,et al. Building Energy an Simulation Model for Analyzing Energy Saving Options of Multi-Span Greenhouses , 2020, Applied Sciences.
[149] Chandra Sekhar,et al. Energy saving estimation for plug and lighting load using occupancy analysis , 2019, Renewable Energy.
[150] N. A. Tunio,et al. Economic and Environmental Analysis of Converting Grid Supplied HPS Lights to solar PV powered LEDs in Street Lighting at Khairpur Mirs’ Pakistan , 2016 .
[151] Anibal T. de Almeida,et al. Energy storage system for self-consumption of photovoltaic energy in residential zero energy buildings , 2017 .
[152] M. H. Haque,et al. Energy cost minimization for net zero energy homes through optimal sizing of battery storage system , 2019, Renewable Energy.
[153] Gábor Pintér,et al. Study of Photovoltaics and LED Energy Efficiency: Case Study in Hungary , 2018 .
[154] Nigel P. Brandon,et al. Multi-criteria evaluation of solid oxide fuel cell based combined cooling heating and power (SOFC-CCHP) applications for public buildings in China , 2017 .
[155] Yang Chen,et al. A collaborative operation decision model for distributed building clusters , 2015 .
[156] Radu Dumitru Pentiuc,et al. A survey on solutions to increase energy efficiency in public lighting system of Romania , 2016, 2016 International Conference on Development and Application Systems (DAS).
[157] Yongming Zhang,et al. A Group Approach of Smart Hybrid Poles with Renewable Energy, Street Lighting and EV Charging Based on DC Micro-Grid , 2018 .
[158] Walid R. Issa,et al. Performance assessment of cadmium telluride-based semi-transparent glazing for power saving in façade buildings , 2020 .
[159] Mohammed Wadi,et al. Smart hybrid wind-solar street lighting system fuzzy based approach: Case study Istanbul-Turkey , 2018, 2018 6th International Istanbul Smart Grids and Cities Congress and Fair (ICSG).
[160] P. Xu,et al. Estimating demand response potential under coupled thermal inertia of building and air-conditioning system , 2019, Energy and Buildings.
[161] R. Pacheco-Torres,et al. Towards successful environmental performance of sustainable cities: Intervening sectors. A review , 2016 .
[162] Omer Tatari,et al. Getting to net zero energy building: Investigating the role of vehicle to home technology , 2016 .
[163] Alan Shu Khen Kwan,et al. Domestic energy consumption patterns in a hot and humid climate: A multiple-case study analysis , 2014 .
[164] Amjad Anvari-Moghaddam,et al. A Novel Operational Model for Interconnected Microgrids Participation in Transactive Energy Market: A Hybrid IGDT/Stochastic Approach , 2020, IEEE Transactions on Industrial Informatics.
[165] P. André,et al. Smart grid energy flexible buildings through the use of heat pumps and building thermal mass as energy storage in the Belgian context , 2015 .
[166] Carlo Roselli,et al. Performance assessment of cogeneration and trigeneration systems for small scale applications , 2016 .
[167] Kamaruzzaman Sopian,et al. Optimal sizing of building integrated hybrid PV/diesel generator system for zero load rejection for , 2011 .
[168] Balázs Csanád Csáji,et al. Intelligent control for energy-positive street lighting , 2016 .
[169] Yan-Wu Wang,et al. Peer-to-Peer Energy Sharing Among Smart Energy Buildings by Distributed Transaction , 2019, IEEE Transactions on Smart Grid.
[170] K. Aliakbari,et al. Sensitivity analysis and multi-objective optimization of energy consumption and thermal comfort by using interior light shelves in residential buildings , 2020 .
[171] Justo García-Sanz-Calcedo,et al. Economic and Environmental Impact of Energy Saving in Healthcare Buildings , 2018 .
[172] H. Taleb,et al. Assessing different glazing to achieve better lighting performance of office buildings in the United Arab Emirates (UAE) , 2020 .
[173] Pertti Järventausta,et al. Using electrical energy storage in residential buildings – Sizing of battery and photovoltaic panels based on electricity cost optimization , 2019, Applied Energy.
[174] Inês L. Azevedo,et al. Edison Revisited: Should we use DC circuits for lighting in commercial buildings? , 2012 .
[175] Saffa Riffat,et al. Emission and economic performance assessment of a solid oxide fuel cell micro-combined heat and power system in a domestic building , 2015 .
[176] Arbab Waheed Ahmad,et al. Energy-Efficient Intelligent Street Lighting System Using Traffic-Adaptive Control , 2016, IEEE Sensors Journal.
[177] Hongbo Ren,et al. Economic and environmental evaluation of micro CHP systems with different operating modes for residential buildings in Japan , 2010 .
[178] Fredrik Haglind,et al. A review of solar energy based heat and power generation systems , 2017 .
[179] A. Gómez-Expósito,et al. Self-sufficient renewable energy supply in urban areas: Application to the city of Seville , 2019, Sustainable Cities and Society.
[180] S. M. Hakimi,et al. Intelligent energy management in off-grid smart buildings with energy interaction , 2020 .
[181] Yutian Liu,et al. Primary Frequency Response From the Control of LED Lighting Loads in Commercial Buildings , 2017, IEEE Transactions on Smart Grid.
[182] Mahdi Shahbakhti,et al. Exergy-wise predictive control framework for optimal performance of MicroCSP systems for HVAC applications in buildings , 2020 .
[183] Prashant Kumar Soori,et al. Lighting control strategy for energy efficient office lighting system design , 2013 .
[184] Shantha Gamini Jayasinghe,et al. AC Ship Microgrids: Control and Power Management Optimization , 2018, Energies.
[185] M. J. Hermoso-Orzáez,et al. Evaluation of Uniformity and Glare Improvement with Low Energy Efficiency Losses in Street Lighting LED Luminaires Using Laser-Sintered Polyamide-Based Diffuse Covers , 2018 .
[186] Seunghwan Yoo,et al. Effect of LED lighting on the cooling and heating loads in office buildings , 2014 .
[187] Zheming Tong,et al. The near-source impacts of diesel backup generators in urban environments , 2015 .
[188] Pablo Hernandez-Leal,et al. Local Energy Markets: Paving the Path Toward Fully Transactive Energy Systems , 2019, IEEE Transactions on Power Systems.
[189] Behnam Mohammadi-Ivatloo,et al. Smart home energy management using hybrid robust-stochastic optimization , 2020, Comput. Ind. Eng..
[190] Antonio Colmenar-Santos,et al. Solutions to reduce energy consumption in the management of large buildings , 2013 .
[191] Alice M. Agogino,et al. Sensor-Based Predictive Modeling for Smart Lighting in Grid-Integrated Buildings , 2014, IEEE Sensors Journal.
[192] Simone Gitto,et al. Economic feasibility of energy efficiency improvements in street lighting systems in Rome , 2018 .
[193] Farkhondeh Jabari,et al. Optimal Short-Term Scheduling of Photovoltaic Powered Multi-chiller Plants in the Presence of Demand Response Programs , 2018 .
[194] Jun‐Ki Choi,et al. Economic and Environmental Impacts of Community-Based Residential Building Energy Efficiency Investment , 2014 .
[195] Lihua Xie,et al. A feedforward neural network based indoor-climate control framework for thermal comfort and energy saving in buildings , 2019, Applied Energy.
[196] Jeng Shiun Lim,et al. Review of distributed generation (DG) system planning and optimisation techniques: Comparison of numerical and mathematical modelling methods , 2017 .
[197] Lin Lu,et al. Wind power evaluation and utilization over a reference high-rise building in urban area , 2014 .
[198] Henrique A. C. Braga,et al. Street lighting system for power quality monitoring and energy-efficient illumination control , 2016, 2016 IEEE 25th International Symposium on Industrial Electronics (ISIE).
[199] Jiaming Li,et al. Optimal sizing of grid-connected photovoltaic battery systems for residential houses in Australia , 2019, Renewable Energy.
[200] J. Reyna,et al. Assessing the Potential to Reduce U.S. Building CO2 Emissions 80% by 2050 , 2019, Joule.
[201] A. Sedziwy,et al. Roadway Lighting Retrofit: Environmental and Economic Impact of Greenhouse Gases Footprint Reduction , 2018, Sustainability.
[202] Boqiang Lin,et al. Impact of energy saving and emission reduction policy on urban sustainable development: Empirical evidence from China , 2019, Applied Energy.
[203] Ronita Bardhan,et al. Towards daylight inclusive bye-law: Daylight as an energy saving route for affordable housing in India , 2016 .
[204] R. El Bachtiri,et al. Assessing the potential of hybrid PV–Wind systems to cover public facilities loads under different Moroccan climate conditions , 2017 .