Estrutura de referência para integração entre avaliação do ciclo de vida e aprendizado de máquina

Autores

DOI:

https://doi.org/10.46421/entac.v20i1.5992

Palavras-chave:

Modelo integrativo, Predição, Otimização, Clusterização

Resumo

Esta pesquisa identifica estudos que associam Avaliação do Ciclo de Vida (ACV) e o aprendizado de máquinas (AP) e elabora uma estrutura de referência de integração entre essas áreas. Para tal, o método estruturalista foi aplicado com o seguinte delineamento: identificação dos elementos para integração a partir de uma Revisão Sistemática de Literatura (RSL), conceituação, estabelecimento das relações entre os elementos, elaboração do modelo estrutural e análise. A estrutura integrativa categoriza e associa elementos característicos da ACV e do AP. O estudo confirmou as etapas da ACV como as categorias de seus elementos, sendo estas: goal and scope definition, life cycle inventory, life cycle impact assessment e interpretation; e relacionada à AP: algorithm. Foi possível verificar que AP auxilia em todos os estágios da ACV, mas recursos como predição, otimização e clusterização variam a depender da etapa e objetivos. A contribuição da estrutura integrativa está no auxílio aos profissionais de ACV na seleção dos diferentes recursos do AP incorporando a inteligência artificial para os diferentes cenários de avaliação de impacto ambiental.

Biografia do Autor

Natalia Nakamura Barros , Universidade Estadual de Campinas

Doutorado em Arquitetura, Tecnologia e Cidade pela Universidade Estadual de Campinas (Campinas - SP, Brasil).

Regina Coeli Ruschel, Universidade Estadual de Campinas

Doutorado em Engenharia Elétrica e da Computação pela Universidade Estadual de Campinas. Professora e pesquisadora colaboradora na Universidade Estadual de Campinas (Campinas - SP, Brasil).

Referências

D’AMICO, B. et al. Machine Learning for Sustainable Structures: A Call for Data. Structures, v. 19, p. 1–4, 1 jun. 2019.

D’AMICO, A. et al. Artificial Neural Networks to assess energy and environmental performance of buildings: An Italian case study.

Journal of Cleaner Production, v. 239, p. 117993, dez. 2019.

LI, Yunpeng et al. A Data-Driven Approach for Improving Sustainability Assessment in Advanced Manufacturing. In: IEEE

INTERNATIONAL CONFERENCE ON BIG DATA (BIG DATA), 2017, Boston, MA. Anais... Boston, MA: IEEE, 2017.

WINSTON, Patrick Henry. Artificial Intelligence. 3rd ed. ed. USA: Addison-Wesley Publishing Company, 1993.

BILAL, Muhammad et al. Big Data in the construction industry: A review of present status, opportunities, and future trends.

Advanced Engineering Informatics, v. 30, p. 500–521, 2016.

WANG, E.; SHEN, Z. Lifecycle Energy Consumption Prediction of Residential Buildings by Incorporating Longitudinal Uncertainties.

Journal of Civil Engineering and Management, v. 19, n. SUPPL.1, p. S161–S171, 2013.

XIA, Liming; LIU, Jingjing. Research on Green Building Assessment System Based on BP neural network and Life Cycle Assessment

(LCA). Applied Mechanics and Materials, v. 357–360, p. pp 508-514, 2013.

DUPREZ, Sandrine et al. Improving life cycle-based exploration methods by coupling sensitivity analysis and metamodels. ]

Sustainable Cities and Society, v. 44, p. 70–84, 2019.

PERROTTA, Federico et al. A machine learning approach for the estimation of fuel consumption related to road pavement rolling

resistance for large fleets of trucks. out. 2018, Belgium. Anais... Belgium: [s.n.], out. 2018. Disponível em:

eprints.nottingham.ac.uk/51400/>.

ZIYADI, Mojtaba; AL-QADI, Imad L. Model uncertainty analysis using data analytics for life-cycle assessment (LCA) applications. The

International Journal of Life Cycle Assessment, v. 24, n. 5, p. 945–959, maio 2019.

MA, Jungmok; KIM, Harrison M. Predictive Usage Mining for Life Cycle Assessment. Transportation Research Part D: Transport and

Environment, v. 38, p. 125–143, 2015.

MARVUGLIA, Antonino; KANEVSKI, Mikhail; BENETTO, Enrico. Machine learning for toxicity characterization of organic chemical

emissions using USEtox database: Learning the structure of the input space. Environment International, v. 83, p. 72–85, 1 out.

AZARI, Rahman et al. Multi-Objective Optimization of Building Envelope Design for Life Cycle Environmental Performance. Energy

and Buildings, v. 126, p. 524–534, 15 ago. 2016.

SCHWARTZ, Yair; RASLAN, Rokia; MUMOVIC, Dejan. Implementing multi objective genetic algorithm for life cycle carbon footprint

and life cycle cost minimisation: A building refurbishment case study. Energy, v. 97, p. 58–68, 15 fev. 2016.

SHI, Qian; XU, Yilong. The Selection of Green Building Materials Using GA-BP Hybrid Algorithm. In: 2009 INTERNATIONAL

CONFERENCE ON ARTIFICIAL INTELLIGENCE AND COMPUTATIONAL INTELLIGENCE, nov. 2009, Shanghai, China. Anais... Shanghai,

China: IEEE, nov. 2009. p. 40–45.

THIRY-CHERQUES, Hermano Roberto. O Primeiro Estruturalismo: Método de Pesquisa para as Ciências da Gestão. RAC, v. 10, n. 2,

p. 137–156, 2006.

DRESCH, Aline; LACERDA, Daniel Pacheco; ANTUNES JUNIOR, Jose Antonio Valle. Design Science Research: A Method for Science

and Technology Advancement. Switzerland: Springer International Publishing, 2015.

FENG, Kailun; LU, Weizhuo; WANG, Yaowu. Assessing Environmental Performance in Early Building Design Stage: An Integrated

Parametric Design and Machine Learning Method. Sustainable Cities and Society, v. 50, p. 101596, 1 out. 2019.

GOLAK, Sławomir et al. Application of Neural Network for the Prediction of Eco-Efficiency. Lecture Notes in Computer Science,

, Berlin, Heidelberg. Anais... Berlin, Heidelberg: Springer, 2011. p. 380–387.

SHARIF, Seyed Amirhosain; HAMMAD, Amin. Developing surrogate ANN for selecting near-optimal building energy renovation

methods considering energy consumption, LCC and LCA. Journal of Building Engineering, v. 25, p. 100790, set. 2019.

TEODOSIO, B. et al. Environmental, economic, and serviceability attributes of residential foundation slabs: A comparison between

waffle and stiffened rafts using multi-output deep learning. Journal of Building Engineering, v. 80, p. 107983, 1 dez. 2023.

JI, Sukwon et al. Effect of realistically estimated building lifespan on life cycle assessment: A case study in Korea. Journal of

Building Engineering, v. 75, p. 107028, 15 set. 2023.

JI, Sukwon; LEE, Bumho; YI, Mun Yong. Building life-span prediction for life cycle assessment and life cycle cost using machine

learning: A big data approach. Building and Environment, v. 205, p. 108267, 1 nov. 2021.

MARTÍNEZ-ROCAMORA, Alejandro et al. Environmental benchmarking of building typologies through BIM-based combinatorial

case studies. Automation in Construction, v. 132, p. 103980, 1 dez. 2021.

ESTEGHAMATI, Mohsen Zaker; FLINT, Madeleine M. Developing data-driven surrogate models for holistic performance-based

assessment of mid-rise RC frame buildings at early design. Engineering Structures, v. 245, p. 112971, 15 out. 2021.

BRAGANÇA, Luís; MUNIESA, María Concepción Verde. Measuring Carbon in Cities and Their Buildings through Reverse

Engineering of Life Cycle Assessment. Applied System Innovation, v. 6, n. 5, p. 76, out. 2023.

KHARBANDA, Kritika et al. LearnCarbon: 40th Conference on Education and Research in Computer Aided Architectural Design in

Europe, eCAADe 2022. In: 42ND ECAADE CONFERENCE 2022 - CO-CREATING THE FUTURE, Proceedings of the International

Conference on Education and Research in Computer Aided Architectural Design in Europe, 2022, Nicosia, Cyprus. Anais... Nicosia,

Cyprus: Education and research in Computer Aided Architectural Design in Europe, 2022. p. 601–610. Disponível em:

www.scopus.com/inward/record.url?scp=85139248291&partnerID=8YFLogxK>. Acesso em: 29 fev. 2024.

KOYAMPARAMBATH, Anish et al. Implementing Artificial Intelligence Techniques to Predict Environmental Impacts: Case of

Construction Products. Sustainability, v. 14, n. 6, p. 1–12, 2022.

SU, Shu et al. Temporal dynamic assessment of household energy consumption and carbon emissions in China: From the

perspective of occupants. Sustainable Production and Consumption, v. 37, p. 142–155, 1 maio 2023.

TOOSI, Hashem Amini et al. A novel LCSA-Machine learning based optimization model for sustainable building design-A case study

of energy storage systems. Building and Environment, v. 209, p. 108656, 1 fev. 2022.

COLLETO, Giseli Mary; GOMES, Vanessa. Exploring Machine Learning-Based Archetypes for Urban Life Cycle Modeling (UBiM). In:

CENTRAL EUROPE TOWARDS SUSTAINABLE BUILDING 2022 (CESB22), 1., 21 dez. 2022, Prague. Anais... Prague: CTU, 21 dez. 2022.

p. 169–175. Disponível em: <https://ojs.cvut.cz/ojs/index.php/APP/article/view/8295>. Acesso em: 22 fev. 2024.

ABDOU, N. et al. Prediction and optimization of heating and cooling loads for low energy buildings in Morocco: An application of

hybrid machine learning methods. Journal of Building Engineering, v. 61, p. 105332, 1 dez. 2022.

ZHOU, Yijun; TAM, Vivian WY.; LE, Khoa N. Trade-off between embodied and operational carbon emissions of residential buildings

in early design stage. In: 36TH INTERNATIONAL CONFERENCE ON EFFICIENCY, COST, OPTIMIZATION, SIMULATION AND

ENVIRONMENTAL IMPACT OF ENERGY SYSTEMS (ECOS 2023), 2023, Las Palmas de Gran Canaria, Spain. Anais... Las Palmas de Gran

Canaria, Spain: ECOS 2023, 2023.

ABOKERSH, Mohamed Hany et al. Sustainability insights on emerging solar district heating technologies to boost the nearly zero

energy building concept. Renewable Energy, v. 180, p. 893–913, 1 dez. 2021.

APELLÁNIZ, Diego; PETTERSSON, Björn; GENGNAGEL, Christoph. A Flexible Reinforcement Learning Framework to Implement

Cradle-to-Cradle in Early Design Stages. 2023, Cham. Anais... Cham: Springer International Publishing, 2023. p. 3–12.

SONG, Junkang et al. Framework on Low-Carbon Retrofit of Rural Residential Buildings in Arid Areas of Northwest China: A Case

Study of Turpan Residential Buildings. Building Simulation, v. 16, n. 2, p. 279–297, 1 fev. 2023.

FARAHZADI, Leila; KIOUMARSI, Mahdi. Application of machine learning initiatives and intelligent perspectives for CO2 emissions

reduction in construction. Journal of Cleaner Production, v. 384, p. 135504, 15 jan. 2023.

GHOROGHI, Ali et al. Advances in Application of Machine Learning to Life Cycle Assessment: A Literature Review. The International

Journal of Life Cycle Assessment, v. 27, n. 3, p. 433–456, 1 mar. 2022.

BARROS, Natalia Nakamura; RUSCHEL, Regina Coeli. Machine Learning for Whole-Building Life Cycle Assessment: A Systematic

Literature Review. In: 18TH INTERNATIONAL CONFERENCE ON COMPUTING IN CIVIL AND BUILDING ENGINEERING, 2021, São

Paulo. Anais... São Paulo: Springer Nature Switzerland, 2021. p. 109–122.

ALGREN, Mikaela; FISHER, Wendy; LANDIS, Amy E. Chapter 8 - Machine learning in life cycle assessment. In: DUNN, Jennifer;

BALAPRAKASH, Prasanna (Org.). . Data Science Applied to Sustainability Analysis. [S.l.]: Elsevier, 2021. p. 167–190. Disponível em:

<https://www.sciencedirect.com/science/article/pii/B9780128179765000097>. Acesso em: 29 fev. 2024.

Downloads

Publicado

2024-10-07

Como Citar

BARROS , Natalia Nakamura; RUSCHEL, Regina Coeli. Estrutura de referência para integração entre avaliação do ciclo de vida e aprendizado de máquina. In: ENCONTRO NACIONAL DE TECNOLOGIA DO AMBIENTE CONSTRUÍDO, 20., 2024. Anais [...]. Porto Alegre: ANTAC, 2024. p. 1–15. DOI: 10.46421/entac.v20i1.5992. Disponível em: https://eventos.antac.org.br/index.php/entac/article/view/5992. Acesso em: 22 dez. 2024.

Edição

Seção

Tecnologia da Informação e Comunicação

Artigos Semelhantes

1 2 3 4 5 6 7 8 9 10 > >> 

Você também pode iniciar uma pesquisa avançada por similaridade para este artigo.