ARCOM

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Adekunle, T O (2019) Field measurements of comfort, seasonal performance and cold stress in cross-laminated timber (CLT) school buildings. Smart and Sustainable Built Environment, 9(04), 655–73.

Aggarwal, A, Rani, A and Kumar, M (2019) A robust method to authenticate car license plates using segmentation and ROI based approach. Smart and Sustainable Built Environment, 9(04), 737–47.

Aggarwal, T and Solomon, P (2019) Quantitative analysis of the development of smart cities in India. Smart and Sustainable Built Environment, 9(04), 711–26.

Agyekum, K, Adinyira, E and Ampratwum, G (2020) Factors driving the adoption of green certification of buildings in Ghana. Smart and Sustainable Built Environment, 9(04), 595–613.

de Laat, P (2019) Resource depletion: where is an intervention most effective?. Smart and Sustainable Built Environment, 8(04), 307–21.

• Type: Journal Article
• Keywords: Effectiveness; Efficiency; Sustainability; Heuristics; Intervention areas; Resource depletion;
• ISBN/ISSN: 2046-6099
• URL: https://doi.org/10.1108/SASBE-02-2018-0008
• Abstract:
  Where does one need to intervene in to be most effective? The purpose of this study is to rank areas of the resource system, according to how much of a change can be expected from interventions in an area, in relation to the problem of depleting resources. Principles of structured analysis are used to model how society uses resources. From this model, nine intervention areas are defined. These intervention areas are ranked in terms of effectiveness, through the use of the analytic hierarchy process. To be most effective, one must prioritize intervention areas as follows: material inputs to the operation phase; process inputs to the operation phase; products’ longevity; process inputs to the manufacturing phase; and material inputs to the manufacturing phase. Most decisions are not made on the basis of rigorous analysis but by using heuristics (rules of thumb). The results of this study are expressed as rules of thumb. They can help decision makers prioritize what is most important, but without imposing new ways of working. In the construction domain, heuristics that generalize the impact of actions (content), instead of intervention areas (context), currently seem to prevail. The heuristics of this study generalize the impact of intervention areas. Therefore, they provide an extra perspective for many decision makers. This extra perspective can help reduce mistakes that are typically made by oversimplifying matters.

Dell'Anna, F, Bottero, M, Becchio, C, Corgnati, S P and Mondini, G (2020) Designing a decision support system to evaluate the environmental and extra-economic performances of a nearly zero-energy building. Smart and Sustainable Built Environment, 9(04), 413–42.

Dewan, S and Singh, L (2020) Use of blockchain in designing smart city. Smart and Sustainable Built Environment, 9(04), 695–709.

du Toit, J and Wagner, C (2020) The effect of housing type on householders' self-reported participation in recycling. Smart and Sustainable Built Environment, 9(04), 395–412.

Ekemode, B G (2019) Impact of urban regeneration on commercial property values in Osogbo, Osun State, Nigeria. Smart and Sustainable Built Environment, 9(04), 557–71.

Eslamirad, N, Malekpour Kolbadinejad, S, Mahdavinejad, M and Mehranrad, M (2020) Thermal comfort prediction by applying supervised machine learning in green sidewalks of Tehran. Smart and Sustainable Built Environment, 9(04), 361–74.

Ghosh, S, Kochhar, K, Sharma, A, Kaushal, S, Agrawal, J, Garg, A, Kumar, A and Dugar, Y (2016) Investigating structure generated turbulence using an unmanned aerial vehicle: A prelude to optimal ventilation strategies in India’s upcoming smart cities. Smart and Sustainable Built Environment, 5(04), 372-92.

Ghosh, S, Kochhar, K, Sharma, A, Kaushal, S, Agrawal, J, Garg, A, Kumar, A and Dugar, Y (2016) Investigating structure generated turbulence using an unmanned aerial vehicle: A prelude to optimal ventilation strategies in India’s upcoming smart cities. Smart and Sustainable Built Environment, 5(04), 372-92.

Hopkins, E A (2016) Barriers to adoption of campus green building policies. Smart and Sustainable Built Environment, 5(04), 340-51.

Hussein, D (2020) A user preference modelling method for the assessment of visual complexity in building façade. Smart and Sustainable Built Environment, 9(04), 483–501.

Khan, N A, Ullah Khan, S, Ahmed, S, Farooqi, I H, Hussain, A, Vambol, S and Vambol, V (2019) Smart ways of hospital wastewater management, regulatory standards and conventional treatment techniques. Smart and Sustainable Built Environment, 9(04), 727–36.

Konstantinou, T, de Jonge, T, Oorschot, L, El Messlaki, S, van Oel, C and Asselbergs, T (2019) The relation of energy efficiency upgrades and cost of living, investigated in two cases of multi-residential buildings in the Netherlands. Smart and Sustainable Built Environment, 9(04), 615–33.

Krueger, K, Stoker, A and Gaustad, G (2019) “Alternative” materials in the green building and construction sector. Smart and Sustainable Built Environment, 8(04), 270–91.

Kumar, A, Jain, S and Yadav, D (2020) A novel simulation-annealing enabled ranking and scaling statistical simulation constrained optimization algorithm for Internet-of-things (IoTs). Smart and Sustainable Built Environment, 9(04), 675–93.

Kumar, V, Hundal, B S and Kaur, K (2019) Factors affecting consumer buying behaviour of solar water pumping system. Smart and Sustainable Built Environment, 8(04), 351–64.

Lau, J L and Hashim, A H (2019) Mediation analysis of the relationship between environmental concern and intention to adopt green concepts. Smart and Sustainable Built Environment, 9(04), 539–56.

Lau, J L, Hashim, A H, Samah, A A and Salim, A S S (2016) Understanding the environmental worldviews of Malaysian project managers. Smart and Sustainable Built Environment, 5(04), 307-24.

Loyola, M (2019) A method for real-time error detection in low-cost environmental sensors data. Smart and Sustainable Built Environment, 8(04), 338–50.

Moshtaghian, F, Golabchi, M and Noorzai, E (2020) A framework to dynamic identification of project risks. Smart and Sustainable Built Environment, 9(04), 375–93.

Ndlangamandla, M G and Combrinck, C (2019) Environmental sustainability of construction practices in informal settlements. Smart and Sustainable Built Environment, 9(04), 523–38.

Opawole, A, Babatunde, S O, Kajimo-Shakantu, K and Ateji, O A (2020) Analysis of barriers to the application of life cycle costing in building projects in developing countries. Smart and Sustainable Built Environment, 9(04), 503–21.

Opoku, D J, Ayarkwa, J and Agyekum, K (2019) Barriers to environmental sustainability of construction projects. Smart and Sustainable Built Environment, 8(04), 292–306.

Prakash, A (2019) Smart Cities Mission in India: some definitions and considerations. Smart and Sustainable Built Environment, 8(04), 322–37.

Rahman, F, Rowlands, I and Weber, O (2017) Do green buildings capture higher market valuations and lower vacancy rates? A Canadian case study of LEED and BOMA-BEST properties. Smart and Sustainable Built Environment, 6(04), 102-15.

Saadi, A and Belhadef, H (2020) Deep neural networks for Arabic information extraction. Smart and Sustainable Built Environment, 9(04), 467–82.

Sahebzadeh, S, Dalvand, Z, Sadeghfar, M and Heidari, A (2018) Vernacular architecture of Iran’s hot regions; elements and strategies for a comfortable living environment. Smart and Sustainable Built Environment, 9(04), 573–93.

Shooshtarian, S and Ridley, I (2016) Determination of acceptable thermal range in outdoor built environments by various methods. Smart and Sustainable Built Environment, 5(04), 352-71.

Susilo, A, Fitriah, F, Sunaryo, Ayu Rachmawati, E T and Suryo, E A (2020) Analysis of landslide area of Tulung subdistrict, Ponorogo, Indonesia in 2017 using resistivity method. Smart and Sustainable Built Environment, 9(04), 341–60.

Tunji-Olayeni, P, Kajimo-Shakantu, K and Osunrayi, E (2020) Practitioners' experiences with the drivers and practices for implementing sustainable construction in Nigeria: a qualitative assessment. Smart and Sustainable Built Environment, 9(04), 443–65.

van Stijn, A and Gruis, V (2020) Towards a circular built environment. Smart and Sustainable Built Environment, 9(04), 635–53.

Xia, B, Rosly, N, Wu, P, Bridge, A and Pienaar, J (2016) Improving sustainability literacy of future quantity surveyors. Smart and Sustainable Built Environment, 5(04), 325-39.