Your search keyword '"Xiu-Zhi Chen"' showing total 6 results

1. A Real-Time Vehicle Detection System under Various Bad Weather Conditions Based on a Deep Learning Model without Retraining

Author

Xiu-Zhi Chen, Chieh-Min Chang, Chao-Wei Yu, and Yen-Lin Chen

Subjects

intelligent traffic system, vehicle detection system, various bad weather conditions, Chemical technology, TP1-1185

Abstract

Numerous vehicle detection methods have been proposed to obtain trustworthy traffic data for the development of intelligent traffic systems. Most of these methods perform sufficiently well under common scenarios, such as sunny or cloudy days; however, the detection accuracy drastically decreases under various bad weather conditions, such as rainy days or days with glare, which normally happens during sunset. This study proposes a vehicle detection system with a visibility complementation module that improves detection accuracy under various bad weather conditions. Furthermore, the proposed system can be implemented without retraining the deep learning models for object detection under different weather conditions. The complementation of the visibility was obtained through the use of a dark channel prior and a convolutional encoder–decoder deep learning network with dual residual blocks to resolve different effects from different bad weather conditions. We validated our system on multiple surveillance videos by detecting vehicles with the You Only Look Once (YOLOv3) deep learning model and demonstrated that the computational time of our system could reach 30 fps on average; moreover, the accuracy increased not only by nearly 5% under low-contrast scene conditions but also 50% under rainy scene conditions. The results of our demonstrations indicate that our approach is able to detect vehicles under various bad weather conditions without the need to retrain a new model.

Published

2020

2. A Deep-Learning-Based Vehicle Detection Approach for Insufficient and Nighttime Illumination Conditions

Author

Ho Kwan Leung, Xiu-Zhi Chen, Chao-Wei Yu, Hong-Yi Liang, Jian-Yi Wu, and Yen-Lin Chen

Subjects

vehicle detection, deep learning, nighttime surveillance, convolutional neural networks, insufficient lighting, ambient illumination, real-time detection, residual architecture, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Most object detection models cannot achieve satisfactory performance under nighttime and other insufficient illumination conditions, which may be due to the collection of data sets and typical labeling conventions. Public data sets collected for object detection are usually photographed with sufficient ambient lighting. However, their labeling conventions typically focus on clear objects and ignore blurry and occluded objects. Consequently, the detection performance levels of traditional vehicle detection techniques are limited in nighttime environments without sufficient illumination. When objects occupy a small number of pixels and the existence of crucial features is infrequent, traditional convolutional neural networks (CNNs) may suffer from serious information loss due to the fixed number of convolutional operations. This study presents solutions for data collection and the labeling convention of nighttime data to handle various types of situations, including in-vehicle detection. Moreover, the study proposes a specifically optimized system based on the Faster region-based CNN model. The system has a processing speed of 16 frames per second for 500 × 375-pixel images, and it achieved a mean average precision (mAP) of 0.8497 in our validation segment involving urban nighttime and extremely inadequate lighting conditions. The experimental results demonstrated that our proposed methods can achieve high detection performance in various nighttime environments, such as urban nighttime conditions with insufficient illumination, and extremely dark conditions with nearly no lighting. The proposed system outperforms original methods that have an mAP value of approximately 0.2.

Published

2019

3. Learning-Directed Dynamic Voltage and Frequency Scaling Scheme with Adjustable Performance for Single-Core and Multi-Core Embedded and Mobile Systems

Author

Yen-Lin Chen, Ming-Feng Chang, Chao-Wei Yu, Xiu-Zhi Chen, and Wen-Yew Liang

Subjects

dynamic voltage and frequency scaling (DVFS), embedded systems, energy consumption, low-power software design, multicore computing systems, mobile devices, Chemical technology, TP1-1185

Abstract

Dynamic voltage and frequency scaling (DVFS) is a well-known method for saving energy consumption. Several DVFS studies have applied learning-based methods to implement the DVFS prediction model instead of complicated mathematical models. This paper proposes a lightweight learning-directed DVFS method that involves using counter propagation networks to sense and classify the task behavior and predict the best voltage/frequency setting for the system. An intelligent adjustment mechanism for performance is also provided to users under various performance requirements. The comparative experimental results of the proposed algorithms and other competitive techniques are evaluated on the NVIDIA JETSON Tegra K1 multicore platform and Intel PXA270 embedded platforms. The results demonstrate that the learning-directed DVFS method can accurately predict the suitable central processing unit (CPU) frequency, given the runtime statistical information of a running program, and achieve an energy savings rate up to 42%. Through this method, users can easily achieve effective energy consumption and performance by specifying the factors of performance loss.

Published

2018

4. Learning-Directed Dynamic Voltage and Frequency Scaling Scheme with Adjustable Performance for Single-Core and Multi-Core Embedded and Mobile Systems

Author

Chao-Wei Yu, Ming-Feng Chang, Xiu-Zhi Chen, Yen-Lin Chen, and Wen-Yew Liang

Subjects

Computer science, 02 engineering and technology, lcsh:Chemical technology, Biochemistry, Article, Analytical Chemistry, mobile devices, energy consumption, 0202 electrical engineering, electronic engineering, information engineering, lcsh:TP1-1185, Electrical and Electronic Engineering, Frequency scaling, Instrumentation, Multi-core processor, dynamic voltage and frequency scaling (DVFS), 020206 networking & telecommunications, Energy consumption, Atomic and Molecular Physics, and Optics, 020202 computer hardware & architecture, multicore computing systems, Computer engineering, low-power software design, Single-core, embedded systems, Central processing unit, Energy (signal processing), Voltage

Abstract

Dynamic voltage and frequency scaling (DVFS) is a well-known method for saving energy consumption. Several DVFS studies have applied learning-based methods to implement the DVFS prediction model instead of complicated mathematical models. This paper proposes a lightweight learning-directed DVFS method that involves using counter propagation networks to sense and classify the task behavior and predict the best voltage/frequency setting for the system. An intelligent adjustment mechanism for performance is also provided to users under various performance requirements. The comparative experimental results of the proposed algorithms and other competitive techniques are evaluated on the NVIDIA JETSON Tegra K1 multicore platform and Intel PXA270 embedded platforms. The results demonstrate that the learning-directed DVFS method can accurately predict the suitable central processing unit (CPU) frequency, given the runtime statistical information of a running program, and achieve an energy savings rate up to 42%. Through this method, users can easily achieve effective energy consumption and performance by specifying the factors of performance loss.

Published

2018

5. A Deep-Learning-Based Vehicle Detection Approach for Insufficient and Nighttime Illumination Conditions

Author

Yen-Lin Chen, Liang Hong-Yi, Chao-Wei Yu, Jian-Yi Wu, Xiu-Zhi Chen, and Ho Kwan Leung

Subjects

Computer science, residual architecture, 02 engineering and technology, lcsh:Technology, Convolutional neural network, lcsh:Chemistry, Vehicle detection, convolutional neural networks, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Computer vision, lcsh:QH301-705.5, Instrumentation, Fluid Flow and Transfer Processes, insufficient lighting, Data collection, Pixel, lcsh:T, business.industry, Process Chemistry and Technology, Deep learning, 020208 electrical & electronic engineering, General Engineering, deep learning, nighttime surveillance, Frame rate, lcsh:QC1-999, real-time detection, Object detection, Computer Science Applications, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, vehicle detection, 020201 artificial intelligence & image processing, Artificial intelligence, lcsh:Engineering (General). Civil engineering (General), Focus (optics), business, lcsh:Physics, ambient illumination

Abstract

Most object detection models cannot achieve satisfactory performance under nighttime and other insufficient illumination conditions, which may be due to the collection of data sets and typical labeling conventions. Public data sets collected for object detection are usually photographed with sufficient ambient lighting. However, their labeling conventions typically focus on clear objects and ignore blurry and occluded objects. Consequently, the detection performance levels of traditional vehicle detection techniques are limited in nighttime environments without sufficient illumination. When objects occupy a small number of pixels and the existence of crucial features is infrequent, traditional convolutional neural networks (CNNs) may suffer from serious information loss due to the fixed number of convolutional operations. This study presents solutions for data collection and the labeling convention of nighttime data to handle various types of situations, including in-vehicle detection. Moreover, the study proposes a specifically optimized system based on the Faster region-based CNN model. The system has a processing speed of 16 frames per second for 500 &times, 375-pixel images, and it achieved a mean average precision (mAP) of 0.8497 in our validation segment involving urban nighttime and extremely inadequate lighting conditions. The experimental results demonstrated that our proposed methods can achieve high detection performance in various nighttime environments, such as urban nighttime conditions with insufficient illumination, and extremely dark conditions with nearly no lighting. The proposed system outperforms original methods that have an mAP value of approximately 0.2.

Published

2019

6. Tracking Positioning Algorithm for Direction of Arrival Based on Direction Lock Loop

Author

Xiu-Zhi Cheng, Da-Rong Zhu, Shen Zhang, and Ping He

Subjects

direction lock loop, DOA Estimate, UKF Filtering, location and tracking, Information technology, T58.5-58.64

Abstract

In order to solve the problem of poor real-time performance, low accuracy and high computational complexity in the traditional process of locating and tracking of Direction of Arrival (DOA) of moving targets, this paper proposes a DOA algorithm based on the Direction Lock Loop (DILL) which adopts Lock Loop structure to realize the estimation and location of DOA and can adjust the direction automatically along with the changes of a signal’s angular variation to track the position of the signal. Meanwhile, to reduce the influence of nonlinearity and noise on its performance, the UKF filter is designed for eliminating interference of the estimated target signal to improve accuracy of the signal tracking and stability of the system. Simulation results prove that the algorithm can not only get a high resolution DOA estimate signal, but can also locate and track multiple mobile targets effectively with enhanced accuracy, efficiency and stability.

Published

2015