研究生: |
劉育承 Yu-Cheng Liu |
---|---|
論文名稱: |
室內環境監測物聯網資料之擴增實境呈現模式 Augmented Reality presentation paradigms of indoor environment monitoring data collected using IoT |
指導教授: |
陳鴻銘
Hung-Ming Chen |
口試委員: |
謝佑明
Yo-Ming Hsieh 蔡孟涵 Meng-Han Tsai |
學位類別: |
碩士 Master |
系所名稱: |
工程學院 - 營建工程系 Department of Civil and Construction Engineering |
論文出版年: | 2021 |
畢業學年度: | 109 |
語文別: | 中文 |
論文頁數: | 96 |
中文關鍵詞: | 物聯網 、室內環境 、監測 、熱舒適度 、擴增實境 |
外文關鍵詞: | IoT, indoor environment, monitoring, thermal comfort, AR |
相關次數: | 點閱:262 下載:2 |
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近年來隨著物聯網(Internet of Things,IoT)相關技術的發展,其應用已遍及各個領域,其中室內環境監測在智慧居家與智慧工廠的領域為常見的應用之一。傳統在呈現室內環境監測結果時常以文字或平面的圖表為主,然而透過此種方式無法看出監測數據在空間中的分布情形。另一方面,市面上常見的數值分析軟體可以透過3D的模式將數值大小利用模型的顏色來呈現,故本研究想藉由此種方式將室內環境監測數據透過3D的模式呈現。但目前在3D的呈現上主要以外部的視角居多,若是以使用者的視角在所在環境中操作不一定能夠適用。另一項視覺化技術擴增實境(Augmented Reality,AR)可以將虛擬內容與現實世界整合,且使用情境為使用者視角下操作,因此適用於將室內監測資料透過此種模式呈現。本研究提出室內環境監測物聯網資料之擴增實境呈現系統,案例中透過測站的環境監測結合行動裝置的視覺化呈現,提出一套整合物聯網與擴增實境的應用模式。另外提出幾種視覺化呈現模式來呈現室內環境監測結果,並透過使用者實際測試與評估保留合適的視覺化模式以及建議參數的範圍,作為日後開發者參考依據。
In recent years, with the development of Internet of Things (IoT) related technologies, its applications have spread to various fields, among which indoor environment monitoring is one of the common applications. Traditionally, indoor environmental monitoring results are presented mainly in text or flat charts, but the distribution of monitoring data in space cannot be seen in this way. On the other hand, common numerical analysis software can present the numerical magnitude in 3D mode using the color of the model. However, the current 3D presentation is mainly based on the external view angle, which may not be applicable if the user's view angle is used in the environment. Augmented Reality (AR) can integrate virtual content with the real world and operate in the user's perspective. Therefore, this study proposes an AR presentation system for indoor environmental monitoring data on IoT. A prototype system combining the environmental monitoring of the sensor with the visual presentation of the mobile device was developed to show the feasibility of such interaction paradigm. Several visualization ways are proposed to present the indoor environmental monitoring results. A case study on the application scenarios of the proposed system was developed to show the feasibility and benefit of such integration.
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