電磁垂直剖面探測浮標如何在低風速下量測海表面波浪頻譜

黃鈺宸; Yu-Chen Huang

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101790

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	許哲源	zh_TW
dc.contributor.advisor	Je-Yuan Hsu	en
dc.contributor.author	黃鈺宸	zh_TW
dc.contributor.author	Yu-Chen Huang	en
dc.date.accessioned	2026-03-04T16:35:19Z	-
dc.date.available	2026-03-05	-
dc.date.copyright	2026-03-04	-
dc.date.issued	2026	-
dc.date.submitted	2026-02-09	-
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101790	-
dc.description.abstract	本研究旨在評估電磁垂直剖面探測浮標（Electromagnetic Autonomous Profiling Explorer, EM-APEX floats）於低風速海域（約 5 ～ 8 m/s）進行海表面波浪量測的可行性與準確性。本研究提出的重心偏心旋轉校正法（Center-of-Gravity Eccentricity Rotation Correction, COG-ERC），可以有效修正儀器重量分布不均造成垂直加速度在量測時產生的偏差，並抑制垂直能量頻譜（E_Z (f)）於低頻區段（0.07<f≤0.1 Hz）的能量異常現象，大幅提升 EM-APEX floats 在方向波譜（E(f,θ)）、示性波高（h_s）、峰值頻率（f_p）與主波方向（θ_p）的估算品質。在 2 具浮標（編號 f9467 與編號 f9474）的資料應用結果顯示，該方法分別使低頻能量降低約 0.804 m^2/Hz 與 4.91 m^2/Hz。為了驗證 EM-APEX floats 在波浪觀測上的表現，本研究將其估算的波浪統計參數與 NTU1 海氣象浮標上的 SVS - 603 波浪計，以及新海研 1 號研究船上的船用標準 X 波段波浪雷達進行跨平臺比對。結果顯示，當平臺間的距離 < 30 km 時，EM-APEX floats 與船用標準 X 波段波浪雷達在三項波浪統計參數的均方根誤差（root mean square error, RMSE）呈現：主波方向偏差（∆θ_p）為 29.29°、示性波高偏差（∆h_s）為 0.35 m、峰值頻率偏差（∆f_p）為 0.010 Hz，與 Beckman (2022) 以及 Lopez 等人 (2019) 的跨平臺研究結果相當，反映 EM-APEX floats 在低風速海況下的波浪觀測結果具有良好的可靠性。然而，當平臺間的距離擴大至 30 ～ 60 km時，∆θ_p 可能 > 90°；距離增加至 60 km 以上時，∆h_s 亦可能 > 0.4 m，顯示波浪場的空間非均勻特性隨平臺間的距離增加而放大，並且使跨平臺比對結果的參考性明顯下降。 EM-APEX floats 並非專為波浪量測所設計的平臺，然而，本研究證實其於低風速海域仍能穩定地提供具物理意義的波浪資訊。若進一步結合其多感測器整合能力與半拉格朗日（semi-Lagrangian）的漂流觀測特性，EM-APEX floats 即能彌補傳統波浪浮標與船載雷達系統在空間覆蓋與水文剖面量測的限制，展現其在海氣交互作用研究、多尺度波浪結構分析與海洋動力探勘的應用潛力，為一項具前景的輔助型觀測平臺。	zh_TW
dc.description.abstract	Electromagnetic Autonomous Profiling Explorer (EM-APEX floats) provide simultaneous measurements of horizontal velocity from electromagnetic sensing and vertical acceleration from inertial sensors, offering a potential approach for estimating surface-wave properties under low-wind conditions. However, wave reconstruction can be biased by the float’s internal mass asymmetry, which introduces a rotation-dependent offset in the vertical acceleration and artificially elevates low-frequency energy in the vertical one-dimensional spectrum (E_Z (f)). To address this issue, we develop a Center-of-Gravity Eccentricity Rotation Correction (COG-ERC) method, which quantifies the systematic acceleration bias as a function of the float’s rotation angle and removes it through bin-averaging method (5°bins). Applying COG-ERC to two EM-APEX floats (f9467 and f9474) effectively suppresses the anomalous low-frequency energy in E_Z (f), reducing the mean energy in the 0.07 < f ≤ 0.10 Hz band by 0.804 m^2/Hz and 4.91 m^2/Hz, respectively. As a result, the reconstructed directional spectra (E(f,θ)) and key wave parameters—significant wave height (h_s), peak frequency (f_p), and dominant wave direction (θ_p)—are substantially improved under low-wind conditions (~5 – 8 m/s). The reliability of EM-APEX wave observations is further assessed through cross-platform comparisons with the SVS-603 wave sensor on the NTU1 buoy and a standard shipborne X-band wave radar onboard NOR1. When the separation distance between platforms is < 30 km, EM-APEX and the X-band radar show good agreement, with root mean square error values of 29.99°for ∆θ_p, 0.35 m for ∆h_s, and 0.010 Hz for ∆f_p, consistent with previous validation studies. In contrast, the comparability degrades as the separation distance increases (30 – 60 km and > 60 km), reflecting the growing influence of spatial wave-field heterogeneity on multi-platform comparisons. Although EM-APEX floats were not originally designed for wave measurements, our results demonstrate that—with appropriate correction—these floats can provide stable and physically meaningful wave information under low-wind conditions. Combined with their multi-sensor capability and semi-Lagrangian sampling characteristics, EM-APEX floats can complement conventional wave buoys and shipborne radar systems by improving spatial coverage while simultaneously resolving hydrographic profiles, highlighting their potential for air–sea interaction studies and multi-scale wave dynamics.	en
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dc.description.tableofcontents	口試委員會審定書 I 致謝 II 摘要 III Abstract IV 目次 V 圖次 IX 表次 XV 符號表 XVI 第一章背景簡介 1 1.1 研究動機與目的 1 1.2 波浪的分類與生成機制 2 1.3 波浪量測方式 4 1.4 EM-APEX floats 於波浪觀測的既有研究成果 10 1.4.1 重建海表面波浪 E(f,θ) 的潛力 10 1.4.2 波浪參數的估算表現與可靠性 11 1.5 研究核心目標與章節安排 12 第二章觀測實驗介紹和波浪觀測儀器 17 2.1 航次介紹 17 2.2 EM-APEX floats 介紹 18 2.2.1 海洋物理參數的量測機制與即時通訊架構 19 2.2.2 加速度計、浮力幫浦（buoyancy pump）與葉片（blades） 20 2.2.3 磁力計（magnetometer）與方向角推算 21 2.2.4 研究資料設定 23 2.3 NTU1 海氣象浮標上的SVS-603波浪感測器（Wave Senser）資料 24 2.4 新海研 1 號研究船的船用標準 X 波段波浪雷達資料 27 第三章估算波浪統計參數 30 3.1 使用 EM-APEX floats 估算 E(f,θ) 30 3.1.1 資料品質控制 30 3.1.2 E(f,θ) 的估算原理與方向矩定義 31 3.1.3 使用最大熵方法重建 E(f,θ) 32 3.1.4 判讀 E(f,θ) 33 3.2 波浪批量參數的計算 34 3.2.1 E(f) 的建立 34 3.2.2 估算 hs 與 fp 35 3.2.3 主波方向的估算 35 第四章 EM-APEX floats 量測波浪的原理 37 4.1 高通濾波器的選用 37 4.2 海水水平速度的取得 37 4.3 海水垂直加速度的處理 39 4.4 取得 Eh(f) 和 Ez(f) 40 4.5 低頻區段 Eh(f) 和 Ez(f) 的能量不一致現象 44 第五章修正 EM-APEX floats 在垂直方向上的頻譜誤差 46 5.1 浮標旋轉頻率對 Ez(f) 的影響 46 5.2 重心偏心旋轉校正法 47 5.3 重心偏心旋轉校正法對 Ez(f) 的改善效果 49 5.4 使用 ck(f) 評估重心偏心旋轉校正法的合理性 51 第六章使用 EM-APEX floats 獲得波浪觀測結果 53 6.1 EM-APEX floats 的波浪觀測結果 53 6.1.1 波浪能量的時變演化 54 6.1.2 風速與波浪關係的再檢視 58 6.2 比較 EM-APEX floats 與 NTU1 海氣象浮標的波浪參數 62 6.2.1 示性波高的比較與分析 64 6.2.2 fp 的比較與分析 65 6.2.3 θp 的比較與分析 66 第七章波浪統計參數的跨平臺比較分析 67 7.1 EM-APEX floats 與 NOR1之間的比較 68 7.1.1 時序變化比較 69 7.1.2 比較 E(f,θ) 71 7.1.3 統計特性比較 78 7.2 NTU1 與 NOR1之間的比較 79 7.2.1 時序變化比較 80 7.2.2 比較 E(f,θ) 80 7.2.3 統計特性比較 82 7.3 使用 NOR1 做為中介平臺比較 EM-APEX floats 與 NTU1 83 7.3.1 空間變化比較 84 7.3.2 統計特性比較 87 第八章討論與結論 90 8.1 延伸分析第 7.3 節的跨平臺比對結果 90 8.1.1 ∆θp 的跨平臺一致性分析 90 8.1.2 ∆hs 的跨平臺一致性分析 91 8.1.3 ∆fp 的跨平臺一致性分析 91 8.1.4 驗證跨平臺波浪參數的合理性 91 8.2 E(f) 中的波浪平衡範圍分析 94 8.2.1 不同觀測平臺的波浪平衡範圍 95 8.3 以 E(f) 分析 EM-APEX floats 與 NTU1 海氣象浮標的 ∆hs 98 8.4 採樣範圍差異造成的取樣偏差 98 8.5 結論 100 8.6 EM-APEX floats 在波浪觀測研究的應用價值 101 附錄 A 不同高通濾波器與不同截止頻率對 Ez(f) 的影響 103 附錄 A - 1. 高通濾波器的介紹 103 附錄 A - 1.1. 二階 Butterworth 高通濾波器 104 附錄 A - 1.2. RC高通濾波器 104 附錄 A - 2. 不同高通濾波器對模擬訊號的濾波效果比較 106 附錄 A - 3. 不同高通濾波器在不同 fc 下對示性波高估算的影響 107 附錄 B 以 E(f) 分析 EM-APEX floats 與 NTU1海氣象浮標的 ∆hs 110 參考文獻 113	-
dc.language.iso	zh_TW	-
dc.subject	海表面波浪	-
dc.subject	電磁垂直剖面探測浮標	-
dc.subject	波浪跨平臺比較	-
dc.subject	方向波譜	-
dc.subject	低風速環境	-
dc.subject	Sea surface wave	-
dc.subject	EM-APEX floats	-
dc.subject	Cross-platform wave comparisons	-
dc.subject	Directional wave spectra	-
dc.subject	Low wind conditions	-
dc.title	電磁垂直剖面探測浮標如何在低風速下量測海表面波浪頻譜	zh_TW
dc.title	Observing Surface Wave Spectra Using EM-APEX floats Under Low Wind Conditions	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	碩士	-
dc.contributor.coadvisor	楊穎堅	zh_TW
dc.contributor.coadvisor	Yiing-Jang Yang	en
dc.contributor.oralexamcommittee	張明輝;張偉裕;林幼淳	zh_TW
dc.contributor.oralexamcommittee	Ming-Huei Chang;Wei-Yu Chang;Yu-Chun Lin	en
dc.subject.keyword	海表面波浪,電磁垂直剖面探測浮標波浪跨平臺比較方向波譜低風速環境	zh_TW
dc.subject.keyword	Sea surface wave,EM-APEX floatsCross-platform wave comparisonsDirectional wave spectraLow wind conditions	en
dc.relation.page	122	-
dc.identifier.doi	10.6342/NTU202600520	-
dc.rights.note	同意授權(全球公開)	-
dc.date.accepted	2026-02-10	-
dc.contributor.author-college	理學院	-
dc.contributor.author-dept	海洋研究所	-
dc.date.embargo-lift	2026-03-05	-
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