智慧型建築(IB, Intelligent Building)之規劃設計為近年各國學者所推行的建築新趨勢；以建築管理的角度看待，智慧型建築不僅是重視系統設備本身的智慧化，亦需要藉由系統間整合與連動管理，達成建築智慧化之目的；而除了建築整體效率外，更應該顧及使用者的身心健康及生活品質，方能創造優質的智慧生活環境。
但就台灣智慧型建築評估體系與實際落實狀況而言，是否真正以「智慧化」的模式進行運轉？實為隱藏於智慧型建築體制發展中亟需面對之課題；因此，本研究針對智慧型建築內之防災、電氣、給排水、空調、通訊及輸送…等設備系統與空間使用之運轉、維護管理予以「自動化」，如:室內二氧化碳濃度到達1000ppm時，應開啟空調系統或對外開口引進新鮮外氣；當室內環境品質達到預設之條件時，便可以自動關閉系統。
故本研究以台灣取得智慧建築標章，最高等級之鑽石級案例－中台灣創新園區作為驗證對象，先行將空間使用性質做分類，並依據各空間所使用之能耗類別，彙整出之於該空間使用總能耗的相關程度，及其對應之各個系統作次序排列，以探討系統間相對應之連動關係與控制邏輯。簡言之，即是利用一系列的邏輯整合判斷式，使建築本體如具有意識形態一般，依不同使用需求或基地環境條件營造出更符合人性化的生活空間，成為一真正智慧化的建築生命體。

To promote carbon-reduction of buildings, increase living qualities and guide the innovative development of the industry, Taiwan has authorized the promotion program of Intelligent Green Buildings in 2010, and the program will be co-organized and led by the government departments in collaboration. However, are these intelligent buildings operating “intelligently” according to the Taiwan Intelligent Building Evaluation System and actual implementation situations? This is a hidden issue within the intelligence system development that needs to be answered.
Hence, this study will focus on the automation of operation and maintenance of environmental factors detected in ICT and the disaster prevention, electrical supply, water supply, wastewater, air- conditioning, communications and transport systems. For example, when indoor carbon dioxide concentration exceeds 1000ppm, the air- conditioning system should open a shaft to allow fresh air to enter; when indoor air quality returns to preset conditions, the system will automatically shut down the ventilation system.
This study shall use Taiwan case studies that have achieved the highest level of Intelligent Building Label as targets and explore the relations and links between the different connected systems and the controlling logics. In other words, it will mean using an integrated series of logic controllers to determine system responses, allowing the building to function with consciousness and create human-centered living spaces according to different requirements or basic environmental factors, so that the building may become a truly intelligent building entity.

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