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Homer’’s Iliad. Book VII

為了解決German General的問題，作者Wesselmann, Katharina 這樣論述：

Since Ameis-Hentze-Cauer (1868-1913) no comprehensive, scholarly commentary of Homer’s Iliad has been published in German. In the meantime considerable progress has been made in many traditional areas of Homeric studies (language, realia, structure etc.). In addition, generally acknowledged new f

ields such as narratology have been systematically studied. Furthermore, the knowledge of the Mycenaean language (Linear B) and oral poetry provide completely new possibilities of textual constitution and analysis. Using the old Ameis-Hentze-Cauer as a starting point, the new commentary reflects the

current scholarship on Homer in a comprehensive way. As a new standard work, the ＂Basel Commentary＂ of the Iliad has received considerable recognition among scholars worldwide. The fresh concept in terms of content and form serves the needs of different groups of users. The commentary primarily aim

s at students and academic teachers (at schools and universities), not only of Classics but also of cultural and literary studies as well as of humanities in general.

German General進入發燒排行的影片

深度學習應用於結構耐震性能評估 – 以後拉式預力預鑄混凝土節塊橋樑為例

為了解決German General的問題，作者曾揚 這樣論述：

非線性增量動力分析（Incremental Dynamic Analysis）是一個用以評估結構耐震性能的方法，該方法透過將地動記錄的強度縮放到不同尺度對結構進行模擬實驗，以獲得強度與結構行為的關係作為評估結構耐震性能的參考。然而，由於非線性增量動力分析耗費的分析成本極高，故通常用於分析的地動記錄數量不多，也因此使得繪製易損性函數（Fragility Function）時可能存在著取樣誤差。且當結構性能產生變化，如預應力損失等，會影響結構行為，需要花費高成本來重新進行分析。故本研究以後拉式預應力預鑄混凝土節塊橋梁為例，嘗試使用深度學習模型來預測結構物的耐震行為，並使用此結果繪製易損性函數來評

估結構的耐震性能，與非線性增量動力分析繪製的結果做比較，評估此方法的可行性。本研究以監督式學習的方式訓練模型，為了獲得監督式學習的訓練數據，以建模軟體(ABAQUS)建構離散有限元素模型，使其承載震波並進行非線性增量動力分析。藉由非線性增量動力分析的位移量製作標籤，並提取地動記錄的特徵及預拉應力的改變倍率作為深度學習模型的輸入資料，進行模型訓練與優化，期望使模型可以延伸使用數值分析的結果來增加耐震性能的評估準確性及降低成本。

Ocular Motor Disorders and Vertigo

為了解決German General的問題，作者Strupp, Michael 這樣論述：

Covering the most relevant central and peripheral ocular motor and vestibular disorders, this clinically-oriented and easy-to-read book describes how to take the history of a patient suffering from double vision, blurred vision, opscillopsia, vertigo, or dizziness. The book also provides a detailed

description of how to examine the central and peripheral ocular motor system and the central and peripheral vestibular system. It gives examples of the most common disorders using typical case reports, clinical findings, and appropriate treatment options. It also outlines the current practical treat

ment of ocular motor and vestibular disorders, which includes physical therapy, drug treatment, surgery, as well as psychotherapy. This concise book will be essential reading for students, general practitioners, and neurologists, as well as ENT specialists in this difficult and complicated area. M

ichael Strupp, MD, FRCP, FANA, FEAN, Professor of Neurology, studied medicine at the Technical University of Aachen and in Rochester, N.Y. Then he worked for three years in basic neurophysiological research, mainly doing patch-clamp recordings (at Baylor College, Houston, in Montpellier and in Munic

h), before he moved to the Department of Neurology at the University and the German Centre for Vertigo and Balance Disorders at the University of Munich, Germany. His particular area of interest is the diagnosis and therapy of vestibular, ocular motor and cerebellar disorders. He is very much engage

d in the ＂International Classification of Vestibular Disorders＂ of the classification committee of the Bárány Society. He is currently Editor-in-Chief of Frontiers in Neuro-otology and Joint Chief Editor of the Journal of Neurology. He has received many clinical and scientific awards, including the

Hallpike-Nylen Award 2106 and the Galenus von Pergamon award 2020, is a very passionate teacher and was awarded ’Best Teacher’ by the German Neurological Society. Thomas Brandt, FRCP, FANA, FEAN, Professor of Neurology, German Center for Vertigo and Balance Disorders, Ludwig-Maximilians University,

Munich, Germany studied medicine at the Universities of Cologne and Essen, Germany. His clinical training was under Richard Jung in Neurology and Clinical Neurophysiology in Freiburg, Germany. From 1976 to 1984 he was Director of the Neurological Clinic of the Alfried Krupp Hospital in Essen, and fr

om 1984 to 2008 Chairman of Neurology and Director of the Department of Neurology, LMU, Munich, Germany. He holds a Hertie Senior Research Professorship since 2008 and was also Chief Executive Director of the German Center for Vertigo and Balance Disorders of LMU, Munich. Prof. Brandt was formerly P

resident of the German Neurological Society, the German Society for Clinical Neurophysiology and Functional Imaging, the International Society for Posture and Gait Research, and the European Neurological Society. He is an honorary member of the German, British, and French Neurological Societies, a m

ember of the European Academy of Sciences and Art, a member of the Bavarian Academy of Sciences, and of the German Academy of Life Scientists, Leopoldina. Awards include the Srinivasan Gold Medal, the Betty and David Koetser Prize for Brain Research, the Bárány Gold Medal, the Doctor Robert Pfleger

Award, the Hans Berger Prize, the Wilhelm Erb Medal, the Federal Cross of Merit, Germany, 2016 Charles Eduard Brown-Séquard Lecture, EAN, Copenhagen, and 2017 Masland Award Lecture, WCN, Tokyo.

黃金血糖試片的導線設計及量測方法與智慧製造之研究

為了解決German General的問題，作者郭欣怡 這樣論述：

摘要 iABSTRACT iiiACKNOWLEDGMENTS viCONTENTS viiLIST OF TABLES xLIST OF FIGURES xviiChapter 1 Introduction 11.1 Research Objectives 11.2 Research Background 2Chapter 2 Literature Review 62.1 Current Problems of Blood Glucose Monitoring Systems 62.2 Recent Advances of BGMS.112.3 Future Trend

s to Design and Manufacture Blood Glucose Monitoring Systems 152.4 Electrochemical Reaction 182.5 Gold Test Strips Made of Printed Circuit Board 23Chapter 3 Experimantal Methods 263.1 Experimental Materials and Instruments 263.1.1 Enzyme Preparation 263.1.2 Gold Glucose Test Strips 263.1.3 Ad

hesive tape 273.1.4 Glucose Test Strip Positioning Fixture 273.1.5 Electrochemical Analysis Fixture for Gold Glucose Test Strips 283.1.6 Precision Balance 293.1.7 Constant Temperature Stirring Tank 293.1.8 Ultrasonic Cleaning Machine 303.1.9 YSI Glucose Analyzer 313.1.10 Electrochemical Analyze

r 323.1.11 Dispensing Machine 333.1.12 Other Accessories 353.2 Principles of Electrochemistry and Sampling of Experimental Data 373.3 Studies on the Effect of Electrode Width and Length 393.4 Studies of the Effect of Electrode Spacing 423.5 Studies on the effect of Pulse Width 473.6 Studies o

n the effect of Sample Interval 493.7 Studies on the Effect of Dwelling Time to Perform CV Measurement after Dispensing 513.8 Studies on the Effect of Gold Thickness 533.9 Effect of Surface Cleaning of Gold Test Strips 553.10 Studies on the Effect of Applied Voltage 583.11 Effect of Measurement

Time 60Chapter 4 Results and Discussion 624.1 Effect of Width and Length on Electrode Electrical Resistance for Gold Test Strips 624.2 Effect of Electrode Spacing, Working Electrode Width, and Gold Thickness 1184.3 Effect of Pulse Width 1454.4 Effect of Sample Interval 1724.5 Effect of Dwell

ing time to Perform CV Measurement after Dispensing 1844.6 Effect of Gold Thickness of Test Strips 1864.7 Effect of Surface Cleaning 1884.8 Effect of Applied Voltage 1924.9 Effect of Measurement Time 2064.10 Apply Cyber Physical System Architecture Concept to Design and Manufacture Blood Glucose

Monitoring Systems 2094.10.1 5C Architecture to Design and Manufacture BGMS 2094.10.2 Smart Connection Level 2094.10.3 Data to Information Conversion Level 2114.10.4 Cyber Level 2124.10.5 Cognition Level 2124.10.6 Configuration Level 212Chapter 5 Conclusion 216Future Studies 218References

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