ARCOM

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Arslan, M, Cruz, C, Roxin, A and Ginhac, D (2018) Spatio-temporal analysis of trajectories for safer construction sites. Smart and Sustainable Built Environment, 7(01), 80–100.

Bebelaar, N, Braggaar, R C, Kleijwegt, C M, Meulmeester, R W E, Michailidou, G, Salheb, N, van der Spek, S, Vaissier, N and Verbree, E (2018) Monitoring urban environmental phenomena through a wireless distributed sensor network. Smart and Sustainable Built Environment, 7(01), 68–79.

Brynskov, M, Heijnen, A, Balestrini, M and Raetzsch, C (2018) Experimentation at scale: challenges for making urban informatics work. Smart and Sustainable Built Environment, 7(01), 150–63.

Dritsa, D and Biloria, N (2018) Towards a multi-scalar framework for smart healthcare. Smart and Sustainable Built Environment, 7(01), 33–52.

Foth, M (2018) Participatory urban informatics: towards citizen-ability. Smart and Sustainable Built Environment, 7(01), 4–19.

Gholami, M, Mofidi Shemirani, M and Fayaz, R (2018) A modelling methodology for a solar energy-efficient neighbourhood. Smart and Sustainable Built Environment, 7(01), 117–32.

• Type: Journal Article
• Keywords: Solar energy; Urban energy planning; Urban form; Neighborhood modelling; Urban daylight; Urban modelling interface (UMI);
• ISBN/ISSN: 2046-6099
• URL: https://doi.org/10.1108/SASBE-10-2017-0044
• Abstract:
  The purpose of this paper is to present a methodology to quantify the solar energy potential for applying photovoltaic systems and find an efficient geometry for urban blocks to obtain a better quality of daylighting in terms of continuous daylight autonomy (DA) and spatial DA with less energy consumption. The paper is based on a complete simulation of the topography and micro-climate of the area under study. Simulations were performed using ArcGIS and Rhinoceros and urban daylight (UD) and urban modeling interface plugin for a neighborhood in the region of Narmak in Tehran, Iran. Five configurations of a neighborhood were compared using simulations. It was found that the impact of the geometrical form on daylight gain and energy consumption is significant and the terraced model is the most suitable form for obtaining a constant floor area ratio. Furthermore, it is an optimal form of urban blocks to gain the most energy through photovoltaic systems in the neighborhood as it would be able to satisfy about 42 percent of the energy needs. Planning to achieve sufficient energy factors in cities is a difficult task, since urban planners often do not have adequate technical knowledge to measure the contribution of solar energy in urban plans and this paper aims to introduce a comprehensive modeling methodology by which the urban energy planning can be used and understood in the urban context to make it completely clear as a strategy of implementation.

Haeusler, M H, Hespanhol, L and Hoggenmueller, M (2018) ParticipationPlus. Smart and Sustainable Built Environment, 7(01), 133–49.

Hussein, D, Sarkar, S and Armstrong, P (2018) Mapping preferences for the number of built elements. Smart and Sustainable Built Environment, 7(01), 53–67.

Muehlbauer, M (2018) Towards typogenetic tools for generative urban aesthetics. Smart and Sustainable Built Environment, 7(01), 20–32.

Nourian, P, Rezvani, S, Valeckaite, K and Sariyildiz, S (2018) Modelling walking and cycling accessibility and mobility. Smart and Sustainable Built Environment, 7(01), 101–16.