ARCOM

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Badasyan, N (2018) Project feasibility analysis economic model for private investments in the renewable energy sector. Built Environment Project and Asset Management, 8(02), 215–30.

Isa, R, Emuze, F, Das, D and Awuzie, B O (2018) Modeling a transformational route to infrastructure sustainability in South Africa. Built Environment Project and Asset Management, 8(02), 147–59.

Lian, J K and Ling, F Y (2018) The influence of personal characteristics on quantity surveyors’ job satisfaction. Built Environment Project and Asset Management, 8(02), 183–93.

Ohueri, C C, Enegbuma, W I and Kenley, R (2018) Energy efficiency practices for Malaysian green office building occupants. Built Environment Project and Asset Management, 8(02), 134–46.

Saeed, A M, Duffield, C and Hui, F K P (2018) An enhanced framework for assessing the operational performance of public-private partnership school projects. Built Environment Project and Asset Management, 8(02), 194–214.

Salvado, F, Almeida, N M d and Vale e Azevedo, A (2018) Toward improved LCC-informed decisions in building management. Built Environment Project and Asset Management, 8(02), 114–33.

• Type: Journal Article
• Keywords: Building management; Asset management; Economic sustainability; Life cycle cost; Facility management; Project; programme and portfolio management;
• ISBN/ISSN: 2044-124X
• URL: https://doi.org/10.1108/BEPAM-07-2017-0042
• Abstract:
  Stakeholders of the Architecture, Engineering and Construction (AEC) sector require information on the buildings economic performance throughout its life cycle. This information is neither readily available nor always accurate because building management (BM) professionals still face difficulties to fully incorporate the life cycle cost (LCC) concept into their daily practice. The purpose of this paper is to identify and contribute to solving these difficulties. This paper provides a background knowledge review and set the ground for a structured research roadmap and a management framework that highlight the links and limitations to be addressed within and between LCC and BM. A six-stage method was used for developing conceptual frameworks targeting six goals: establishing a point of departure; mapping sources of information; literature research; notion deconstruction and conceptual categorization; overview of the applicable background knowledge; and structuring of a framework for LCC-informed decisions in BM. Management solutions for the built context are necessarily connected with LCC and BM current concepts such as asset management, project, program and portfolio management, facility management and data management. These management approaches highlight the importance of incorporating life cycle concepts and promote LCC effective application within the AEC sector. This paper identifies and discusses current limitations on the information availability for the economic performance of buildings throughout its life cycle. This work also identifies LCC-related topics that need to be further explored or addressed by both the scientific community and practitioners to overcome these limitations and facilitate the integration of the LCC concept into BM activities.

Shahandashti, M, Ashuri, B and Mostaan, K (2018) Automatic fault detection for Building Integrated Photovoltaic (BIPV) systems using time series methods. Built Environment Project and Asset Management, 8(02), 160–70.

Vilventhan, A and Kalidindi, S N (2018) Utility relocation management in highway projects. Built Environment Project and Asset Management, 8(02), 171–82.