為了要開發一高準確率及低複雜度之心電圖訊號特徵萃取系統，利用與心電圖訊號在波型上相似之基底進行特徵萃取的概念是本論文達到高準確偵測的主要策略，而考慮基線飄移雜訊所帶來的影響並且在特徵萃取過程中解決以省略“基線飄移雜訊去除”的步驟是本論文主要降低複雜度的概念；為了達到這些目標，本論文主要提出賈伯小波轉換、不同尺度高斯匹配分析等方法開發出一無須去除基線飄移之心電圖訊號萃取系統；最後，根據主觀及客觀之實驗結果，本論文所提出之無須去除基線飄移演算法不僅有準確偵測結果外，本演算法也可適用於較多種不同之心電圖訊號。因此，本演算法的應用層面不論對於傳統幫助醫療診斷亦或是現今及未來發展中較新穎的即時診斷、健康雲及健康照護等等之應用皆非常適合；另外，本演算法亦可實現在不同平台上，不管是軟體、硬體或嵌入式系統的平台等，都可節省運算時間或消耗能源。

In order to develop a high accuracy and low complexity ECG feature extraction algorithm, using the concept of waveform similarity measurement among the ECG features and corresponding similar bases is the main strategy for accuracy improvement; considering the influences caused by baseline drift noise and solving them during the processing procedures of feature extraction to omit the step of “baseline drift removal” is the major tactic for complexity reduction. Based on these purposes, the primarily detecting methods including Gabor wavelet transform and matching process using half Gaussian model with various scales are proposed to develop an accurate ECG feature extraction systems without baseline drift removal. Finally, subjective and objective experimental results present that proposed baseline drift removal omission algorithm can not only extract the useful features correctly but also be applicable for widely types of ECG signals. Therefore, the proposed algorithm is suitable for not only traditional medical diagnosis but also more novel applications in real-time, health-cloud, health-care systems, etc. In addition, the proposed algorithm could also be implemented on various platforms such as software, hardware, or embedded systems, which may reduce the computing time or power consumption.

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