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研究生: Rex Aurelius Castillo Robielos
Rex Aurelius Castillo Robielos
論文名稱: 道路和行人安全交通標誌理解框架的開發與應用
Development and Application of Traffic Sign Comprehension Framework for Road and Pedestrian Safety
指導教授: 林久翔
Chiuhsiang Joe Lin
口試委員: Yu-Chung Tsao
Yu-Chung Tsao
Kung Jeng Wang
Kung Jeng Wang
Bernard Jiang
Bernard Jiang
Tien-Lung Sun
Tien-Lung Sun
Li Yonghui
Li Yonghui
學位類別: 博士
Doctor
系所名稱: 管理學院 - 工業管理系
Department of Industrial Management
論文出版年: 2023
畢業學年度: 111
語文別: 英文
論文頁數: 56
中文關鍵詞: traffic sign comprehensiontraffic accidents and violationsroad safetycognitive design features
外文關鍵詞: traffic sign comprehension, traffic accidents and violations, road safety, cognitive design features
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Traffic sign comprehension plays an important role in road and pedestrian safety. Thus, several studies have already been conducted on traffic sign comprehension, but those studies have focused on different sign factors ranging from driver’s characteristics, display condition, and ergonomic principles, to name a few, that can affect the observed level of comprehension. Currently, no existing framework would comprehensively show the systematic assessment of traffic sign comprehension. To bridge this gap, in this dissertation, the current study identified the influential factors considered in various traffic sign comprehension literature, grouped them into useful categories, and then developed a conceptual framework to comprehensively consolidate how this research field has progressed through the years. The framework consisted of eight categories: Design characteristics, non-Design characteristics, Cognitive Design Features, Evaluation Tool/Equipment, Test Format, Types of Statistical Analysis/Algorithms, Study population, and Target Users. This framework can be used as a guide in conducting future traffic sign comprehension research.
The current study also examined 73 existing traffic signs in Metro Manila for their matching accuracy, matching time, and cognitive design features. A total of 60 Filipinos (30 drivers and 30 non-drivers) were voluntarily recruited to perform a matching-based comprehension test. In a matching-based comprehension test, the traffic sign is matched with the most appropriate referent name which shows a clear-cut distinction between wrong and correct answers. To assess the signs’ acceptability in a matching test, a level of at least 67% accuracy must be obtained in a comprehension test. For matching accuracy, 27 of the 73 traffic signs did not comply with the 67% comprehension standard set by ISO 3864-1:2011. Drivers were found to have better matching accuracy for both regulatory and warning signs compared to non-drivers. Traffic signs displayed in symbols had the lowest matching accuracy and the slowest matching time. When the text was added to traffic signs displayed in symbols, matching accuracy and matching time improved significantly. However, signs displayed in text only obtained the highest matching accuracy and fastest matching time. The cognitive design features, which were the measurement of a sign’s design, were also assessed through their familiarity, concreteness, complexity, and semantic distance. Cognitive design features were found to be positively correlated to matching accuracy for both regulatory and warning signs but negatively correlated to matching time for warning signs. For signs displayed in symbols, cognitive design features were also found to be correlated to matching accuracy and matching time. To improve comprehension and road safety, semantic distance, concreteness, and familiarity are the key cognitive design features that must be considered by traffic sign designers. Also, the Philippines’ Department of Transportation can adopt the matching test of the current study as a mandatory retraining requirement for the renewal of a driver’s license. In addition, our matching-based comprehension test can also be applied and extended to evaluate the existing traffic signs worldwide.


Traffic sign comprehension plays an important role in road and pedestrian safety. Thus, several studies have already been conducted on traffic sign comprehension, but those studies have focused on different sign factors ranging from driver’s characteristics, display condition, and ergonomic principles, to name a few, that can affect the observed level of comprehension. Currently, no existing framework would comprehensively show the systematic assessment of traffic sign comprehension. To bridge this gap, in this dissertation, the current study identified the influential factors considered in various traffic sign comprehension literature, grouped them into useful categories, and then developed a conceptual framework to comprehensively consolidate how this research field has progressed through the years. The framework consisted of eight categories: Design characteristics, non-Design characteristics, Cognitive Design Features, Evaluation Tool/Equipment, Test Format, Types of Statistical Analysis/Algorithms, Study population, and Target Users. This framework can be used as a guide in conducting future traffic sign comprehension research.
The current study also examined 73 existing traffic signs in Metro Manila for their matching accuracy, matching time, and cognitive design features. A total of 60 Filipinos (30 drivers and 30 non-drivers) were voluntarily recruited to perform a matching-based comprehension test. In a matching-based comprehension test, the traffic sign is matched with the most appropriate referent name which shows a clear-cut distinction between wrong and correct answers. To assess the signs’ acceptability in a matching test, a level of at least 67% accuracy must be obtained in a comprehension test. For matching accuracy, 27 of the 73 traffic signs did not comply with the 67% comprehension standard set by ISO 3864-1:2011. Drivers were found to have better matching accuracy for both regulatory and warning signs compared to non-drivers. Traffic signs displayed in symbols had the lowest matching accuracy and the slowest matching time. When the text was added to traffic signs displayed in symbols, matching accuracy and matching time improved significantly. However, signs displayed in text only obtained the highest matching accuracy and fastest matching time. The cognitive design features, which were the measurement of a sign’s design, were also assessed through their familiarity, concreteness, complexity, and semantic distance. Cognitive design features were found to be positively correlated to matching accuracy for both regulatory and warning signs but negatively correlated to matching time for warning signs. For signs displayed in symbols, cognitive design features were also found to be correlated to matching accuracy and matching time. To improve comprehension and road safety, semantic distance, concreteness, and familiarity are the key cognitive design features that must be considered by traffic sign designers. Also, the Philippines’ Department of Transportation can adopt the matching test of the current study as a mandatory retraining requirement for the renewal of a driver’s license. In addition, our matching-based comprehension test can also be applied and extended to evaluate the existing traffic signs worldwide.

Table of Contents Abstract……………………………………………………………………….............................. i Acknowledgments……………………………………………………………................... iii List of Tables…………………………………………………………………........................... vi List of Figures…………………………………………………………………..........................vii CHAPTER 1 INTRODUCTION……………………………………………........................ 1 1.1 Background and Justification of the Study…………………………............. 1 1.2 Study Motivation and Objectives……………………………………................. 4 1.3 Study Framework……………………………………………………........................... 5 1.4 Scope and Limitation of the Study…………………………………................... 6 CHAPTER 2 LITERATURE REVIEW……………………………………............................7 2.1 Driver’s Characteristics…………………………................................................ 7 2.2 Design Characteristics……………………………………........................................8 2.3 Cognitive Design Features……………………………………..................... 12 2.4 Traffic Sign Comprehension Test Format……………………......................13 2.5 Traffic Sign Evaluation Tool or Equipment………………………….......... 14 2.6 Type of Statistical Analysis or Algorithm…………………......................... 15 2.7 Study Population and Target Road Users……………………….................. 16 2.8 Traffic Sign Comprehension Conceptual Framework…………............16 CHAPTER 3 METHODOLOGY……………………………………………...................... 22 3.1 Participants………………………………………………………................................ 23 3.2 Equipment and Computer Programs………………………………........... 24 3.3 Procedures…………………………………………………………............................. 24 3.4 Data Analysis……………………………………………………….......................... 27 CHAPTER 4 RESULTS……………………………………………………..................... 28 4.1 Introduction………………………………………………………............................. 28 4.2 Matching Accuracy ………………………………………………....................... 28 4.3 Matching Time……………………………………………………....................... 31 4.4 Cognitive Design Features………………………………………......................... 33 CHAPTER 5 DISCUSSION………………………………………………........................ 36 CHAPTER 6 CONCLUSION AND FUTURE DIRECTIONS……………............ 45 REFERENCES……………………………………………………………................................. 50

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