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| 研究生: |
林志陽 Chih-Yang Lin |
|---|---|
| 論文名稱: |
商用GPS射頻前端模組積體電路應用於太空環境之輻射照射測試探討 A Study of GPS RF Front End IC COTS Component Application in Space Radiation Environment |
| 指導教授: |
高維文
Wei-Wen Kao |
| 口試委員: |
陳亮光
Liang-Kuang Chen 張浩基 Hao-Chi Chang 林志勳 Chih-Hsun Lin |
| 學位類別: |
碩士 Master |
| 系所名稱: |
工程學院 - 機械工程系 Department of Mechanical Engineering |
| 論文出版年: | 2012 |
| 畢業學年度: | 100 |
| 語文別: | 中文 |
| 論文頁數: | 92 |
| 中文關鍵詞: | 商用等級之現貨組件 、游離輻射 、總游離劑量 、美國軍規標準 、射頻前端元件 |
| 外文關鍵詞: | Commercial-Off-The-Shelf, COTS, ionizing radiation, Total Ionizing Dose, TID, US MIL-STD, RF Front End, RFFE |
| 相關次數: | 點閱:249 下載:5 |
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在日漸普及與依賴全球定位系統(Global Positioning System, GPS)的今日,其在小型實驗型之衛星導航與相關衍生應用科學上亦已成為一個極具吸引力的研究主題。然而符合太空等級的GPS接收機,其成本亦往往令人咋舌。因此,如何利用現今之商用等級之現貨組件(Commercial-Off-The-Shelf , COTS),在經過一連串太空等級之各項環境測試與篩選等程序,使之成為一合格且符合合理成本考量下之太空等級產品,則不失為一可行且務實之變通辦法。
其中,太空環境條件對電子元件之影響與一般大氣環境最大的差別條件之一則是游離輻射(ionizing radiation)。而也基於太空輻射環境之限制考量下,對於一般商用GPS元件欲應用於太空飛行者,亦勢必要對其進行一連串之總游離劑量(Total Ionizing Dose, TID)輻射照射測試。
基於上述理由,本文將先對於太空環境以及其對於半導體電子元件可能造成之效應與影響作一了解後,再參考美國軍規標準MIL-STD-883G Method 1019.4 ,針對不同之GPS之前端射頻元件(RF Front End, RFFE)執行不同程度之總游離劑量(Total Ionizing Dose, TID)輻射照射測試,並比較有無遮蔽保護條件下之實驗結果進行比較分析,藉以驗證其在輻射環境下之性能、可靠性與存活率。
Today, the growing popularity of global positioning system (GPS) application has become more and more attractive topic for both scientific and navigation experiment onboard a small satellite project. Due to space qualified GPS receiver is always beyond economic budget constrain. Therefore, how to utilize the current stock of commercial grade components (Commercial-Off-The-Shelf, COTS) to going through a series of space level of the environmental testing and screening procedure(s), is considered a practical approach under a reasonable cost.
Especially space ionizing radiation environment is the most different between normal ambient application case. Therefore, the Total Ionizing Dose(TID) will be conducted and analyzed to evaluate the space application potential or capability of general commercial GPS component.
For the above reasons, this study will understand the space environment conditions and associated effect on semi-conduct electronic component first, then reference the MIL-STD-883G, Method 1019.4, to conduct a different GPS Radio Frequency Front End component under different level of Total Ionizing Dose(TID) exposure with different shield effect tests, in order to verify its performance、reliability and survival in a radiation environment condition.
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