Abstract
Building energy efficiency, as a traditional field which has been existing for decades performs a prosperous needs with diversity of corresponding methods. In the flow of artificial intelligence (AI) background, where does the building energy efficiency advance and how does it emphasize? This question seems to become more significant with the blueprints of zero energy building implementation issued by many countries. The major objective of this research is to review, analyze and identify the performance of AI based applications in buildings, especially for building energy efficiency and zero energy building. Based on the present research trends, the possible changes AI based approach brings to related laws, regulations and standards are firstly analyzed. The main aspects of the AI based approach infrastructure in buildings is thoroughly reviewed and compared. IoT based sensor applications for thermal comfort, platforms and algorithms for building multi energies control, and forecasting methods for building load, subsystem performance and structure safety are summarized. To provide more optimal references for zero energy building solutions, the AI based approach in zero energy building is then predicted in detail, with particular analysis of occupant presence and behaviors. Finally, the future directions of the research on AI based applications for zero energy building implementation are summarized.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- HVAC:
-
Heating, ventilating and air-conditioning
- AI:
-
Artificial intelligence
- IoT:
-
Internet of things
- ZEB:
-
Zero energy building
- nZEB:
-
Nearly zero energy building
- UEB:
-
Ultra-low energy building
- ASHRAE:
-
American Society of Heating, Refrigerating, Air-Conditioning Engineers
- IES:
-
The Illuminating Engineering Society of North America
- USGBC:
-
US Green Building Council
- IECC:
-
International Energy Conservation Code
- ICC:
-
International Code Council
- ANN:
-
Artificial neural network
- GCHP:
-
Ground-coupled heat pump system
- PV:
-
Photovoltaic
- TLBO:
-
Teaching–learning-based optimization
- ABC:
-
Artificial bee colony
- TLABC:
-
Teaching-learning-based artificial bee colony
- MPPT:
-
Maximum power point tracking
- FL:
-
Fuzzy logic
- PID:
-
Proportional-Integral-Derivative
- PSO:
-
Particle Swarm Optimization
- PPD:
-
Predicted Percentage of Dissatisfied
- GA:
-
Genetic Algorithms
- SVR:
-
Support vector regression
- SVM:
-
Support vector machine
- CRT:
-
Classification and regression tree
- GLR:
-
General linear regression
- CAID:
-
Chi-squared automatic interaction detector
- EIM:
-
Ensemble inference model
- SI:
-
Swarm intelligence
- PLS:
-
Partial least squares regress
- WT:
-
Wavelet transform
- FDD:
-
Fault detection and diagnosis
- VIC:
-
Virtual in situ sensor calibration
- MCMC:
-
Markov chain Monte Carlo
References
AGENCY (2015) For natural resources and energy, energy conservation and renewable energy department, summary report of committee ZEB Road-map. METI. http://www.METI.go.jp/press/2015/12/20151217002/20151217002-1.pdf
Ahn J, Cho S (2017) Anti-logic or common sense that can hinder machine’s energy performance: energy and comfort control models based on artificial intelligence responding to abnormal indoor environments. Appl Energy 204:117–130
Ahn K-U, Kim D-W, Park C-S, de Wilde P (2017) Predictability of occupant presence and performance gap in building energy simulation. Appl Energy 208:1639–1652
Aïssani A, Chateauneuf A, Fontaine J-P, Audebert P (2016) Quantification of workmanship insulation defects and their impact on the thermal performance of building facades. Appl Energy 165:272–284
Amasyali K, El-Gohary NM (2018) A review of data-driven building energy consumption prediction studies. Renew Sustain Energy Rev 81(1):1192–1205
ANSI/ASHRAE Standard 55-2017 (2017) ANSI/ASHRAE. Thermal environmental conditions for human occupancy (ANSI/ASHRAE Standard 55-2017)
ANSI/ASHRAE/IES Standard 90.1-2016 (2016) ANSI/ASHRAE/IES. Energy standard for buildings except low-rise residential buildings (ANSI/ASHRAE/IES Standard 90.1-2016)
ANSI/BICSI-007 2017 (2017) ANSI/BICSI. Design and implementation practices for intelligent buildings (ANSI/BICSI-007 2017)
Asensio OI, Delmas MA (2017) Corrigendum: The effectiveness of US energy efficiency building labels. Nat Energy 2:17033
Ballif C, Perret-Aebi L-E, Lufkin S, Rey E (2018) Integrated thinking for photovoltaics in buildings. Nat Energy 3:438–442
Baloch AA, Shaikh PH, Shaikh F, Leghari ZH, Mirjat NH, Uqaili MA (2018) Simulation tools application for artificial lighting in buildings. Renew Sustain Energy Rev 82:3007–3026
Bello-Orgaz G, Jung J, Camacho D (2016) Social big data: recent achievements and new challenges. Inf Fusion 28:45–59
Bonabeau E, Dorigo M, Theraulaz G (1999) Swarm intelligence: from natural to artificial systems. Oxford University Press Inc, New York, p 307
Building Energy Research Center of Tsinghua University (2018) China building energy use 2018. https://berc.bestchina.org/Files/CBEU2018.pdf
Butler D (2008) Architecture: architects of a low-energy future. Nature 452:520–523
Casado-Vara R, Martin-del Rey A, Affes S, Prieto J, Corchado JM (2020) IoT network slicing on virtual layers of homogeneous data for improved algorithm operation in smart buildings. Future Gener Comput Syst 102:965–977
Chang S, Yang PPJ, Yamagata Y, Tobey MB (2020) Chapter 3—Modeling and design of smart buildings. Urban systems design. Elsevier, Amsterdam, pp 59–86
Chen X, Bin X, Mei C, Ding Y, Li K (2018) Teaching-learning-based artificial bee colony for solar photovoltaic parameter estimation. Appl Energy 212:1578–1588
Chou J-S, Bui D-K (2014) Modeling heating and cooling loads by artificial intelligence for energy-efficient building design. Energy Build 82:437–446
Daikin Company (2017) Sustainability report 2017. https://www.daikin.com/csr/report/2017web/web_daikin_csr2017_all_en.pdf
Daut MAM, Hassan MY, Abdullah H, Rahman HA, Abdullah MP, Hussin F (2017) Building electrical energy consumption forecasting analysis using conventional and artificial intelligence methods: a review. Renew Sustain Energy Rev 70:1108–1118
Davis SJ, Lewis NS, Shaner M et al (2018) Net-zero emissions energy systems. Science 360(6396):eaas9793. https://doi.org/10.1126/science.aas9793
Deb C, Lee SE, Santamouris M (2018) Using artificial neural networks to assess HVAC related energy saving in retrofitted office buildings. Sol Energy 163:32–44
Delgarm N, Sajadi B, Delgarm S (2016) Multi-objective optimization of building energy performance and indoor thermal comfort: a new method using artificial bee colony (ABC). Energy Build 131:42–53
Deutsche Energie-Agentur (dena). Statistics & facts of buildings. https://www.dena.de/en/topics-projects/energy-efficiency/buildings/
Dong B, Yan D, Li Z, Jin Y, Feng X, Fontenot H (2018) Modeling occupancy and behavior for better building design and operation—a critical review. Build Simul 11(5):899–921
Dong B, Prakash V, Feng F, O’Neill Z (2019) A review of smart building sensing system for better indoor environment control. Energy Build 199:29–46
EIA (2019) Energy consumption by sector. Energy. http://www.eia.gov/totalenergy/data/monthly/pdf/sec2_3.pdf
Energy Performance of Building Directive (EPBD) (2009). 17 Nov 2009. http://www.estif.org/policies/epbd0
Esbensen TV, Korsgaard V (1977) Dimensioning of the solar heating system in the zero energy house in Denmark. Sol Energy 19(2):195–199
Esen H, Inalli M, Sengur A, Esen M (2008) Artificial neural networks and adaptive neuro-fuzzy assessments for ground-coupled heat pump system. Energy Build 40:1074–1083
Europe Union (2020) Intelligent energy-Europe nearly zero-energy building strategy 2020. https://ec.europa.eu/energy/intelligent/projects
Executive Order 13514 (2015) Federal leadership in environmental, energy, and economic performance (US). 5 Oct 2009 and Revoked by: EO 13693, 19 Mar 2015
GB50314-2015 (2015) Ministry of housing and urban rural development of China/general administration of quality supervision, inspection and quarantine of China. Smart building design standard (GB50314-2015) China Architecture and Building Press, Beijing
GB/T51161-2016 (2016) Ministry of housing and urban rural development of China/general administration of quality supervision, inspection and quarantine of China. Standard for energy consumption of building (GB/T51161-2016) China Architecture and Building Press, Beijing
GBT 51350-2019 (2019) Ministry of housing and urban rural development of China/general administration of quality supervision, inspection and quarantine of China. Technical standard for near zero energy building (GBT 51350-2019) China Architecture and Building Press, Beijing
Hakimi SM, Hasankhani A (2020) Intelligent energy management in off-grid smart buildings with energy interaction. J Clean Prod 244:118906
Han KH, Zhang J (2020) Energy-saving building system integration with a smart and low-cost sensing/control network for sustainable and healthy living environments: demonstration case study. Energy Build 214:109861
Hao G, Longshu L, Chuanjian Y et al (2019) Incremental reduction algorithm with acceleration strategy based on conflict region. Artif Intell Rev 51:507. https://doi.org/10.1007/s10462-017-9570-6
Heng J, Wang J, Xiao L, Haiyan L (2017) Research and application of a combined model based on frequent pattern growth algorithm and multi-objective optimization for solar radiation forecasting. Appl Energy 208:845–866
Hua M, Hai W, Weiding L (2017) District-energy planning method based on energy bus system in hot summer and cold winter areas. J Refrig 4:50–58
Hui Z, Xiu Y, Shengyuan Z (2010) Enlightenment from German building energy efficiency standard evolution. Eco-city Green Build 3:40–44
IEA (2019) Global energy & CO2 status report 2019, IEA, Paris. https://www.iea.org/reports/global-energy-co2-status-report-2019
Iqbal J, Khan M, Talha M, Farman H, Jan B, Muhammad A, Khattak HA (2018) A generic internet of things architecture for controlling electrical energy consumption in smart homes. Sustain Cities Soc 43:443–450
ISO 7730 (2005) ISO. Ergonomics of the thermal environment — Analytical determination and interpretation of thermal comfort using calculation of the PMV and PPD indices and local thermal comfort criteria (ISO 7730: 2005)
ISO 16484-1 (2010) ISO. Building automation and control systems project specification and implementation (ISO 16484-1 2010)
Jaffe AM (2016) The role of the US in the geopolitics of climate policy and stranded oil reserves. Nat Energy 1(10):16158
Jain RK, Qin J, Rajagopal R (2017) Data-driven planning of distributed energy resources amidst socio-technical complexities. Nat Energy 2:17112
Jeyaprabha SB, Selvakumar AI (2015) Optimal sizing of photovoltaic/battery/diesel based hybrid system and optimal tilting of solar array using the artificial intelligence for remote houses in India. Energy Build 96:40–52
JGJ 26-1986 (1986) Ministry of ministry of urban and rural construction and environmental protection of China. Energy conservation design standard for new heating residential buildings (JGJ 26-1986) China Architecture and Building Press, Beijing
JGJ 26-1995 (1995) Ministry of construction of China. Energy conservation design standard for new heating residential buildings (JGJ 26-1995) China Architecture and Building Press, Beijing
JGJ 26-2010 (2010) Ministry of housing and urban rural development of China. Design standard for energy efficiency of residential buildings in severe cold and cold zones (JGJ 26-2010) China Architecture and Building Press, Beijing
Jha SK, Bilalovic J, Jha A, Patel N, Zhang H (2017) Renewable energy: present research and future scope of artificial intelligence. Renew Sustain Energy Rev 77:297–317
Jones N (2018) How to stop data centres from gobbling up the world’s electricity. Nature 561:163–166. https://doi.org/10.1038/d41586-018-06610-y
Kermadi M, Berkouk EM (2017) Artificial intelligence-based maximum power point tracking controllers for photovoltaic systems: comparative study. Renew Sustain Energy Rev 69:369–386
Khajenasiri I, Estebsari A, Verhelst M, Gielen G (2017) A review on internet of things solutions for intelligent energy control in buildings for smart city applications. Energy Procedia 111:770–779
Kim J, Zhou Y, Schiavon S, Raftery P, Brager G (2018) Personal comfort models: predicting individuals’ thermal preference using occupant heating and cooling behavior and machine learning. Build Environ 129:96–106
Kim H, Ahn E, Shin M, Sim S-H (2019) Crack and noncrack classification from concrete surface images using machine learning. Struct Health Monit 18(3):725–738
Koseleva N, Ropaite G (2017) Big data in building energy efficiency: understanding of big data and main challenges. Procedia Eng 172:544–549
Kumar NM, Mallick PK (2018) The Internet of Things: insights into the building blocks, component interactions, and architecture layers. Procedia Comput Sci 132:109–117
Kwan Y, Guan L (2015) Design a zero energy house in Brisbane, Australia. Procedia Eng 121:604–611
Lan B (2014) Comparative study of Sino and American building energy efficiency codes and standards. PhD dissertation of Huazhong University of Science and Technology
Lazrak A, Leconte A, Chèze D, Fraisse G, Papillon P, Souyri B (2015) Numerical and experimental results of a novel and generic methodology for energy performance evaluation of thermal systems using renewable energies. Appl Energy 158:142–156
Li J (2016) Energy performance heterogeneity in China’s buildings sector: a data-driven investigation. Renew Sustain Energy Rev 58:1587–1600
Li K, Xie X, Xue W, Xiaoli Dai X, Chen XY (2018) A hybrid teaching-learning artificial neural network for building electrical energy consumption prediction. Energy Build 174:323–334
Li X, Liu X, Li CZ, Hu Z, Shen GQ, Huang Z (2019) Foundation pit displacement monitoring and prediction using least squares support vector machines based on multi-point measurement. Struct Health Monit 18(3):715–724
Linder L, Vionnet D, Bacher J-P, Hennebert J (2017) Big building data—a big data platform for smart buildings. Energy Procedia 122:589–594
Liu J, Yao R, Wang J, Li B (2012) Occupants’ behavioural adaptation in workplaces with non-central heating and cooling systems. Appl Therm Eng 35:40–54
Liu Y, Zhang S, Xu W, Cho D (2016) Study of zero energy building development in Korea. Build Sci 32(6):171–177
Liu Y, Yu N, Wang W, Guan X, Xu Z, Dong B, Liu T (2018a) Coordinating the operations of smart buildings in smart grids. Appl Energy 228:2510–2525
Liu D, Yancai X, Wei Q, Liu X (2018b) Residential energy scheduling for variable weather solar energy based on adaptive dynamic programming. IEEE/CAA J Autom Sin 5(01):36–46
Loveday DL, Virk GS (1992) Artificial intelligence for buildings. Appl Energy 41:201–221
Magalhães SMC, Leal VMS, Horta IM (2017) Modelling the relationship between heating energy use and indoor temperatures in residential buildings through Artificial Neural Networks considering occupant behavior. Energy Build 151:332–343
Martín-Garín A, Millán-García JA, Baïri A, Millán-Medel J, Sala-Lizarraga JM (2018) Environmental monitoring system based on an Open Source Platform and the Internet of Things for a building energy retrofit. Autom Constr 87:201–214
Mearian L (2016) Google’s DeepMind AI can slash data center power use 40%. IDG Communications, Inc, Massachusetts
MGuirk PM, Dowling R, Carr C (2019) The material politics of smart building energy management: a view from Sydney’s commercial office space. Polit Geogr 74:102034
Mohammadi M, Noorollahi Y, Mohammadi-ivatloo B, Yousefi H (2017) Energy hub: from a model to a concept—a review. Renew Sustain Energy Rev 80:1512–1527
Molina-Solana M, Ros M, Ruiz MD, Gómez-Romero J, Martin-Bautista MJ (2017) Data science for building energy management: a review. Renew Sustain Energy Rev 70:598–609
Na W, Wei X (2016) Research on international zero energy consumption building technology policy. Constr Sci Technol 10:30–33
Najafi A, Falaghi H, Contreras J, Ramezani M (2016) Medium-term energy hub management subject to electricity price and wind uncertainty. Appl Energy 168:418–433
Najafi-Ghalelou A, Zare K, Nojavan S (2019) Risk-based scheduling of smart apartment building under market price uncertainty using robust optimization approach. Sustain Cities Soc 48:101549
Najeh H, Singh MP, Chabir K, Ploix S, Abdelkrim MN (2018) Diagnosis of sensor grids in a building context: application to an office setting. J Build Eng 17:75–83
Nalmpantis C, Vrakas D (2019) Machine learning approaches for non-intrusive load monitoring: from qualitative to quantitative comparation. Artif Intell Rev 52:217–243
Naylor S, Gillott M, Lau T (2018) A review of occupant-centric building control strategies to reduce building energy use. Renew Sustain Energy Rev 96:1–10
Nord N, Tereshchenko T, Qvistgaard LH, Tryggestad IS (2018) Influence of occupant behavior and operation on performance of a residential Zero Emission Building in Norway. Energy Build 159:75–88
Papatsimpa C, Linnartz JPMG (2018) Propagating sensor uncertainty to better infer office occupancy in smart building control. Energy Build 179:73–82
Paudel S, Elmtiri M, Kling WL, Le Corre O, Lacarrière B (2014) Pseudo dynamic transitional modeling of building heating energy demand using artificial neural network. Energy Build 70:81–93
Pezeshki Z, Mazinani SM (2019) Comparison of artificial neural networks, fuzzy logic and neuro fuzzy for predicting optimization of building thermal consumption: a survey. Artif Intell Rev 52:495–525
Plageras AP, Psannis KE, Stergiou C, Wang H, Gupta BB (2018) Efficient IoT-based sensor BIG Data collection-processing and analysis in smart buildings. Future Gener Comput Syst 82:349–357
Rad ZR, Ghobadi MS, Yakhchalian M (2019) Probabilistic seismic collapse and residual drift assessment of smart buildings equipped with shape memory alloy connections. Eng Struct 197:109375
Raza MQ, Khosravi A (2015) A review on artificial intelligence based load demand forecasting techniques for smart grid and buildings. Renew Sustain Energy Rev 50:1352–1372
Reyna JL, Chester MV (2017) Energy efficiency to reduce residential electricity and natural gas use under climate change. Nat Commun 8:14916. https://doi.org/10.1038/ncomms14916
Robu Valentin DF (2017) Artificial intelligence: outsmart supply dips in renewable energy. Nature 544(7649):161. https://doi.org/10.1038/544161b
Sembroiz D, Careglio D, Ricciardi S, Fiore U (2019) Planning and operational energy optimization solutions for smart buildings. Inf Sci 476:439–452
Singh P, Dwivedi P (2018) Integration of new evolutionary approach with artificial neural network for solving short term load forecast problem. Appl Energy 217:537–549
Sovacool BK, Rio DDF (2020) Smart home technologies in Europe: a critical review of concepts, benefits, risks and policies. Renew Sustain Energy Rev 120:109663
Tabor DP, Roch LM, Saikin SK, Kreisbeck C, Sheberla D, Montoya JH, Dwaraknath S, Aykol M, Ortiz C, Tribukait H, Amador-Bedolla C, Brabec CJ, Maruyama B, Persson KA, Aspuru-Guzik A (2018) Accelerating the discovery of materials for clean energy in the era of smart automation. Nat Rev Mater 3:5–20
Torcellini PA, Crawley DB (2006) Understanding zero-energy buildings. ASHRAE J 48(9):62–68
Tsang SW, Jim CY (2016) Applying artificial intelligence modeling to optimize green roof irrigation. Energy Build 127:360–369
Van Cutsem O, Dac DH, Boudou P, Kayal M (2020) Cooperative energy management of a community of smart-buildings: a blockchain approach. Int J Electr Power Energy Syst 117:105643
Venkatesan K, Ramachandraiah U (2018) Climate responsive cooling control using artificial neural networks. J Build Eng 19:191–204
Voss K, Musall E, Lichtmeß M (2011) From low-energy to net zero-energy buildings: status and perspectives. J Green Build 6(1):46–57
Wang Z, Srinivasan RS (2017) A review of artificial intelligence based building energy use prediction: Contrasting the capabilities of single and ensemble prediction models. Renew Sustain Energy Rev 75:796–808
Wang L, Lee EWM, Yuen RKK (2018) Novel dynamic forecasting model for building cooling loads combining an artificial neural network and an ensemble approach. Appl Energy 228:1740–1753
Wang Yu, Yan X, Tang Y (2019) Distributed aggregation control of grid-interactive smart buildings for power system frequency support. Appl Energy 251:113371
Wei Y, Zhang X, Shi Y, Xia L, Pan S, Jinshun W, Han M, Zhao X (2018) A review of data-driven approaches for prediction and classification of building energy consumption. Renew Sustain Energy Rev 82(1):1027–1047
Weiding L, Wei B, Peipei W, Hao L (2018) New energy management technologies for net zero building energy community. HV&AC 48(7):31–39
Xu W, Sun D, Lu F, Yu Z, Wang J (2018) Research progress and reflection on the definition and technical index system of nearly zero-energy building. Build Sci 34(4):1–9
Yan D, Hong T, Dong B, Mahdavi A, D’Oca S, Gaetani I, Feng X (2017) IEA EBC Annex 66: definition and simulation of occupant behavior in buildings. Energy Build 156:258–270
Yang I-H, Yeo M-S, Kim K-W (2003) Application of artificial neural network to predict the optimal start time for heating system in building. Energy Convers Manag 44:2791–2809
Yoganathan D, Kondepudi S, Kalluri B, Manthapuri S (2018) Optimal sensor placement strategy for office buildings using clustering algorithms. Energy Build 158:1206–1225
Yoon S, Yuebin Yu (2018) Strategies for virtual in situ sensor calibration in building energy systems. Energy Build 172:22–34
Yousefi F, Gholipour Y, Yan W (2017) A study of the impact of occupant behaviors on energy performance of building envelopes using occupants’ data. Energy Build 148:182–198
Zhang S, Xu W, Jiang Y, Feng W, Sun D, Liu Z (2013) Research on definition development and main content of zero energy building. Build Sci 29(10):114–120
Zhao J, Liu X (2018) A hybrid method of dynamic cooling and heating load forecasting for office buildings based on artificial intelligence and regression analysis. Energy Build 174:293–308
Zhou N, Khanna N, Feng W, Ke J, Levine M (2018) Scenarios of energy efficiency and CO2 emissions reduction potential in the buildings sector in China to year 2050. Nat Energy 3:978–984
Acknowledgements
This work was partially supported by the Project of Guangdong University of Technology (2018-148/134, Exploration Study of Talents Fostering in Building Environment and Energy Engineering Based on AI Techniques).
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Yan, B., Hao, F. & Meng, X. When artificial intelligence meets building energy efficiency, a review focusing on zero energy building. Artif Intell Rev 54, 2193–2220 (2021). https://doi.org/10.1007/s10462-020-09902-w
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10462-020-09902-w