鯨豚哨叫聲自動化偵測方法之性能評估研究

邱元肇; Yuan-Chao Chiu

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101851

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	陳琪芳	zh_TW
dc.contributor.advisor	Chi-Fang Chen	en
dc.contributor.author	邱元肇	zh_TW
dc.contributor.author	Yuan-Chao Chiu	en
dc.date.accessioned	2026-03-05T16:10:22Z	-
dc.date.available	2026-03-06	-
dc.date.copyright	2026-03-05	-
dc.date.issued	2026	-
dc.date.submitted	2026-02-03	-
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101851	-
dc.description.abstract	本研究旨在針對鯨豚哨叫聲自動化偵測方法建立一套標準化且易於實作的性能評估流程，以解决不同偵測方法之性能比較不易的問題。本研究提出兩種基於頻譜偵測概念的匹配流程，作為量化偵測性能的統一評估架構。研究錄音資料取自臺灣西部彰濱工業區及線西水道鄰近海域之豐富哨叫聲時段，比較三種偵測方法（NTUPAM、GM-PHD與PAMGuard）在時間網格匹配（TGM）與輪廓匹配（CM）下的偵測表現。TGM衡量哨叫聲是否真實存在的判定能力，CM用於衡量輪廓追蹤能力，兩流程採用tLimit、tgroup、SNRthr、dfthr與ratiodf等匹配閾值探討其對偵測結果的影響，以精確率（Precision）、召回率（Recall）與F1分數（F1-score）作為性能評估指標，並依據閾值設定自動排除不可納入評估計算的資料。結果顯示，提升tLimit或SNRthr會降低可評估樣本比例使Precision下降；提升tgroup可減少漏檢使Recall提升；降低ratiodf則可減輕局部離群輪廓點的影響，使更多輪廓通過dfthr檢核提升整體偵測性能。在偵測方法比較上，NTUPAM於TGM中有最高Precision（0.8660），較不易出現真實哨叫聲的誤判（FP），但於輪廓追蹤表現較差；GM-PHD於TGM與CM皆有最高Recall（0.9273；0.8669），顯示其具有良好輪廓追蹤性能，且最能避免漏檢（FN）；PAMGuard則於兩流程均獲最高F1-score（0.8668；0.8508），呈現整體均衡的偵測性能。此外，本研究發現部分性能指標（如Accuracy、Error Rate）在長期尺度資料下易受高佔比之TN主導，不一定可有效反應偵測性能，應釐清分析時段與資料規模對此類指標表現的潛在影響。本研究所建置的性能評估流程具備彈性與可擴充性，未來可納入更多場域資料與偵測方法，使匹配流程更趨完善，並整合至自動化偵測平台，以期建立更具普適性與實務價值的鯨豚聲學偵測性能比較框架。	zh_TW
dc.description.abstract	This study aims to establish a standardized and easily implementable performance evaluation process for automatic cetacean whistle detection methods, addressing the difficulty of comparing detection performance across different algorithms. Two matching procedures based on spectrogram-based concepts are proposed as a unified framework for quantifying detection performance. The analyzed acoustic recordings were collected from whistle-rich periods in the coastal waters near the Changbin Industrial Park and the Xianxi Channel in western Taiwan. Three detection methods—NTUPAM, GM-PHD, and PAMGuard were compared under two matching procedures: Time-Grid Matching (TGM) and Contour Matching (CM). TGM evaluates the detector’s ability to determine the actual presence of whistles, while CM focuses on contour-tracking performance. Both procedures employ matching thresholds including tLimit, tgroup, SNRthr, dfthr and ratiodf to examine their influence on detection outcomes. Precision, Recall, and F1-score are used as performance metrics, and data that do not meet evaluation conditions are automatically excluded based on threshold settings. Results show that increasing tLimit or SNRthr reduces the proportion of evaluable samples, leading to decreased Precision; increasing tgroup reduces missed detections and thus improves Recall; lowering ratiodf mitigates the influence of local outlier contour points, allowing more contours to pass the dfthr criterion and improving overall detection performance. In comparing the three detection methods, NTUPAM achieved the highest Precision (0.8660) in TGM, indicating fewer false positives for true whistle occurrences, though its contour-tracking performance was relatively poor. GM-PHD achieved the highest Recall in both TGM and CM (0.9273; 0.8669), suggesting strong contour-tracking ability and minimal missed detections (FN). PAMGuard obtained the highest F1-score in both procedures (0.8668; 0.8508), demonstrating balanced overall performance. Additionally, this study found that certain metrics (such as Accuracy and Error Rate) are easily dominated by the high proportion of TN in long-duration datasets, which may not effectively reflect detection performance; therefore, the potential influence of analysis duration and data scale on such metrics should be carefully examined. The performance evaluation process developed in this study possesses flexibility and extensibility. Future work may incorporate additional datasets from various environments and a broader range of detection methods to further refine the matching procedures and integrate them into automated detection platforms, with the goal of establishing a more universally applicable and practically valuable framework for cetacean acoustic detection performance assessment.	en
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dc.description.tableofcontents	謝誌 i 摘要 ii Abstract iii 目次 iv 圖次 vi 表次 xv 符號表 xvi 第一章緒論 1 1.1 前言 1 1.2 研究動機與目的 2 1.3 文獻回顧 3 1.3.1 鯨豚鳴音與行為模式 3 1.3.2 哨叫聲自動偵測方法 5 1.3.3 哨叫聲偵測性能評估 7 第二章研究方法 11 2.1 研究場域與實驗儀器 11 2.2 哨叫聲輪廓人工標註 14 2.2.1 Spectrogram時間軸與頻率軸 15 2.2.2 功率頻譜密度（Power Spectral Density, PSD） 17 2.2.3 時頻譜圖對比度 18 2.2.4 輪廓標註與自動修正 19 2.3 哨叫聲自動偵測方法 22 2.3.1 NTUPAM 22 2.3.2 PAMGuard – Whistle and Moan Detector 24 2.3.2.1 Whistle and Moan Detector哨叫聲偵測模組 24 2.3.2.2 PAMGuard模組設定 28 2.3.3 GM-PHD濾波器 30 2.3.3.1 目標追蹤與狀態空間模型 31 2.3.3.2 機率假設密度（PHD）濾波器 33 2.3.3.3 預測與更新方程優化 35 2.3.3.4 高斯混合機率假設密度（GM-PHD）濾波器[52] 36 2.3.3.4.1 初始化（Initialization） 38 2.3.3.4.2 預測（Prediction） 38 2.3.3.4.3 更新（Update） 40 2.3.3.4.4 剪枝（Pruning）與合併（Merging） 41 2.3.3.4.5 狀態估計與追蹤 42 2.4 哨叫聲偵測模型性能評估流程 43 2.4.1 哨叫聲輪廓資料庫 43 2.4.2 時間網格匹配（Time-Grid Matching, TGM） 44 2.4.3 輪廓匹配（Contour Matching, CM） 47 2.5 匹配閾值（Matching Thresholds） 50 第三章結果分析與討論 53 3.1 偵測參數與匹配閾值 53 3.2 哨叫聲資料庫概述 55 3.3 偵測結果分析 59 3.3.1 時間網格匹配整體結果分析 59 3.3.2 時間網格匹配案例分析 66 3.3.3 輪廓匹配整體結果分析 70 3.3.4 輪廓匹配案例分析 81 3.4 性能評估指標分析與討論 86 3.4.1 偵測模型性能比較 86 3.4.2 納入TN之評估指標（Accuracy、Error rate）比較分析 89 第四章結論建議與未來展望 91 4.1 結論 91 4.2 建議與未來展望 93 參考文獻 95 附錄I 納入平均計算之長度比例ratiodf選擇 101 附錄II 不同tLimit、ratiodf對應之Precision熱圖（CM，0-3600s，dfthr=281.25Hz） 102 附錄III 不同tLimit、ratiodf對應之Recall熱圖（CM，0-3600s，dfthr=281.25Hz） 119 附錄IV 不同tLimit、ratiodf對應之F1-score熱圖（CM，0-3600s，dfthr=281.25Hz） 136 附錄V SNRthr = 10dB之輪廓匹配性能分析 153 附錄VI 簡單型與複雜型輪廓匹配性能分析 154 附錄VII 980-990s分析範圍之時頻譜與對應GT/DT輪廓分布 157 附錄VIII 哨叫聲六類型別每分鐘數量統計 158	-
dc.language.iso	zh_TW	-
dc.subject	被動式聲學監測	-
dc.subject	鯨豚哨叫聲	-
dc.subject	NTUPAM	-
dc.subject	GM-PHD	-
dc.subject	PAMGuard	-
dc.subject	時間網格匹配	-
dc.subject	輪廓匹配	-
dc.subject	Passive Acoustic Monitoring	-
dc.subject	Cetacean Whistles	-
dc.subject	NTUPAM	-
dc.subject	GM-PHD	-
dc.subject	PAMGuard	-
dc.subject	Time-Grid Matching	-
dc.subject	Contour Matching	-
dc.title	鯨豚哨叫聲自動化偵測方法之性能評估研究	zh_TW
dc.title	A Study on the Performance Evaluation for Automatic Detection of Cetacean Whistles	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	黃維信;胡惟鈞;洪靖唐	zh_TW
dc.contributor.oralexamcommittee	Wei-Shien Hwang;Wei-Chun Hu;Ching-Tang Hung	en
dc.subject.keyword	被動式聲學監測,鯨豚哨叫聲NTUPAMGM-PHDPAMGuard時間網格匹配輪廓匹配	zh_TW
dc.subject.keyword	Passive Acoustic Monitoring,Cetacean WhistlesNTUPAMGM-PHDPAMGuardTime-Grid MatchingContour Matching	en
dc.relation.page	162	-
dc.identifier.doi	10.6342/NTU202600517	-
dc.rights.note	未授權	-
dc.date.accepted	2026-02-05	-
dc.contributor.author-college	工學院	-
dc.contributor.author-dept	工程科學及海洋工程學系	-
dc.date.embargo-lift	N/A	-
顯示於系所單位：	工程科學及海洋工程學系

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