| 姓名 |
徐永林(HSU,YUNG-LIN)
查詢紙本館藏 |
畢業系所 |
資訊管理學系在職專班 |
| 論文名稱 |
RF(無線射頻)裝置國際認證自動化解決方案-以E公司為例
(An Automated Solution for International Certifications of Radio Frequency Devices – The Case of Company E)
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| 相關論文 | |
| 檔案 |
 [Endnote RIS 格式]
[Bibtex 格式]
 [相關文章]  [文章引用]  [完整記錄]  [館藏目錄]  至系統瀏覽論文 ( 永不開放)
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| 摘要(中) |
隨時科技發展愈來愈快,RF (Radio Frequency) 無線射頻的技術與產品也一直不斷推層出新,例如:物聯網IoT (Internet of Things),車聯網、智慧城市Smart City,智慧電網Smart Grid以及未來的5G通訊。
其中又以物聯網的發展最為迅速,物聯網能讓所有無線電子產品實現互聯互通,其中,通訊技術與標準扮演關鍵性角色。在全球自由貿易的潮流下,各國政府為了產品的品質與安全,製訂了不同的規範。除了符合各技術聯盟的規範要求,無線及通訊產品在上市前,廠商應同步符合各國的法規要求,且法規不斷的更新,語言障礙與不同國家所需複雜的認證是最常面臨的出口障礙。
本研究的個案E公司,為國際認證公司,負責產品測試及驗證。目前為人工設定儀器參數值及手動控制設備運轉,執行測試。但產品測試法規眾多,各國法規皆不盡相同,測試儀器參數及測試場地皆為不同,只要一個參數設定錯誤,將會面臨退件及重測,耗時費工,缺乏工作效益及測試的準確性。
本研究目的在提出一個有效的測試方案,規劃一套自動化驗證系統。首先撰寫程式,用電腦控制,將各場地之測試儀器透過GPIB介面串連,並將所有測試項目串連,再將所有單項指令整合至一個完整的產品測試指令集。此改善方案經過可行性分析,確認為可行之方案。本案可有效地降低驗證所需時間以及人力等成本,增進測試準確度與效能,亦可提升所屬公司保持良好的競爭優勢。 |
| 摘要(英) |
Coupled with the phenomenal development in technology, RF (Radio frequency) technologies and products have also been continuously updated. These include the Internet of Things (IoT), Internet of Vehicles, Smart City, Smart Grid and future 5G communications.
The development of the Internet of Things is the fastest among these. IoT enables all wireless electronic products to be interconnected. Communication technologies and standards play a key role in its development. Under the trend of global free trade, governments of various countries have formulated different standards to ensure quality and safety for various products. Besides complying with the specifications of various technical alliances, manufacturers must also comply with the requirements of various national laws and regulations before the wireless and communication products can be launched into the respective markets. Language barriers and the complex certification procedures required in different countries are the most commonly encountered trade barriers.
Company E in this study is an international certification company responsible for product testing and verifications. At present, to accomplish all required testing procedures, staffs have to manually set the instrument parameter values and manually control the operation of the equipment before conducting tests. However, there are numerous product testing regulations, and all national laws and regulations are different. The test instrument parameters and required settings are all different. If a parameter is set incorrectly, it will face returning and retesting, which is time consuming and labor intensive.
This study attempts to plan for an automated verification system. To prove the concept, the programs required for computer to control, connect the testing equipment of each site through the GPIB interface were developed, connecting all the test items serially, and then integrate all the individual instructions into a complete product testing instruction set. The concept was proven valid. The improvement plan including the service standard operations procedures was also confirmed through feasibility analysis. This proposal can effectively reduce the time required for verification and manpower and other costs, improve test accuracy and efficiency, and improve the company′s competitive advantage. |
| 關鍵字(中) |
★ 無線射頻
★ 物聯網
★ 自動化測試系統 |
關鍵字(英) |
★ RF (Radio frequency)
★ Internet of Things (IoT)
★ Automated testing system |
| 論文目次 |
摘要 i
Abstract ii
誌謝 iii
目錄 iv
圖目錄 v
表目錄 vi
第一章 緒論 1
1.1 背景 1
1.2 動機 1
1.3 目的 2
1.4 研究架構 3
第二章 文獻探討 4
2.1 國際法規制定組織 4
2.2 無線技術聯盟組織 8
第三章 產業背景及個案分析 13
3.1 電子商品驗證產業背景 13
3.2 公司介紹 16
3.3 公司面臨之問題 17
第四章 個案的改善方案 27
4.1 建置目標 28
4.2 測試需求分析 28
4.3 測試項目分析 31
4.4 自動化測試系統建置 42
4.5 自動化測試系統驗證成果 46
4.6 可行性分析 55
第五章 結論與建議 57
4.7 流程改善結果與效益 57
4.8 未來改善方向與建議 57
參考文獻 59 |
| 參考文獻 |
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4. FCC (2016), KDB 974614 D01 Accredited Test Lab Roles and Resp v04, FCC
5. FCC (2017), KDB 558074 D01 DTS Meas Guidance v04, FCC
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13. 國家通訊傳播委員會 (2007),2.4GHz射頻電信終端設備技術規範,台北市:國家通訊傳播委員會。
14. 國家通訊傳播委員會 (2018a),低功率射頻電機技術規範,台北市:國家通訊傳播委員會。
15. 國家通訊傳播委員會 (2018b),國家通訊傳播委員會本會沿革,https://www.ncc.gov.tw/chinese/content.aspx?site_content_sn=3419&is_history=0,accessed on 2018.05.26。
16. 經濟部標準檢驗局 (2006),CNS 13438資訊技術設備-射頻干擾特性-限制值與量測方法, 台北市:經濟部標準檢驗局。
17. 經濟部標準檢驗局 (2018),經濟部標準檢驗局組織架構及職掌圖,https://www.bsmi.gov.tw/wSite/ct?xItem=3374&ctNode=2659,accessed on 2018.05.26
18. 維基百科 (2018a) ,IEEE 802.11, https://zh.wikipedia.org/wiki/IEEE_802.11, accessed on 2018.05.26
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22. 謝中欽 (2012),行動通訊裝置國際認證自動化解決方案─以Q公司為例,國立中央大學碩士論文 |
| 指導教授 |
范錚強
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審核日期 |
2018-7-6 |
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