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Journal articles on the topic 'Transfer learning'

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Published: 4 June 2021
Last updated: 14 September 2024

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1

Alla, Sri Sai Meghana, and Kavitha Athota. "Brain Tumor Detection Using Transfer Learning in Deep Learning." Indian Journal Of Science And Technology 15, no. 40 (October 27, 2022): 2093–102. http://dx.doi.org/10.17485/ijst/v15i40.1307.

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2

Xu, Mingle, Sook Yoon, Jaesu Lee, and Dong Sun Park. "Unsupervised Transfer Learning for Plant Anomaly Recognition." Korean Institute of Smart Media 11, no. 4 (May 31, 2022): 30–37. http://dx.doi.org/10.30693/smj.2022.11.4.30.

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Disease threatens plant growth and recognizing the type of disease is essential to making a remedy. In recent years, deep learning has witnessed a significant improvement for this task, however, a large volume of labeled images is one of the requirements to get decent performance. But annotated images are difficult and expensive to obtain in the agricultural field. Therefore, designing an efficient and effective strategy is one of the challenges in this area with few labeled data. Transfer learning, assuming taking knowledge from a source domain to a target domain, is borrowed to address this issue and observed comparable results. However, current transfer learning strategies can be regarded as a supervised method as it hypothesizes that there are many labeled images in a source domain. In contrast, unsupervised transfer learning, using only images in a source domain, gives more convenience as collecting images is much easier than annotating. In this paper, we leverage unsupervised transfer learning to perform plant disease recognition, by which we achieve a better performance than supervised transfer learning in many cases. Besides, a vision transformer with a bigger model capacity than convolution is utilized to have a better-pretrained feature space. With the vision transformer-based unsupervised transfer learning, we achieve better results than current works in two datasets. Especially, we obtain 97.3% accuracy with only 30 training images for each class in the Plant Village dataset. We hope that our work can encourage the community to pay attention to vision transformer-based unsupervised transfer learning in the agricultural field when with few labeled images.
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3

Tejaswini, Dubasi, and Uma Rani Vanamala. "Security System based on Transfer Learning Model." International Journal of Science and Research (IJSR) 12, no. 10 (October 5, 2023): 1144–49. http://dx.doi.org/10.21275/sr231013184540.

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4

Würschinger, Hubert, Matthias Mühlbauer, and Nico Hanenkamp. "Transfer Learning für visuelle Kontrollaufgaben/Potentials of Transfer Learning." wt Werkstattstechnik online 110, no. 04 (2020): 264–69. http://dx.doi.org/10.37544/1436-4980-2020-04-98.

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In der industriellen Praxis wird eine Vielzahl von Prozess- und Qualitätskontrollaufgaben visuell von Mitarbeitern oder mithilfe von Kamerasystemen durchgeführt. Durch den Einsatz Künstlicher Intelligenz (KI) lässt sich die Programmierung und damit die Implementierung von Kamerasystemen effizienter gestalten. Im Bereich der Bildanalyse können dabei vortrainierte Künstliche Neuronale Netze verwendet werden. Das Anwenden dieser Netze auf neue Aufgaben wird dabei Transfer Learning genannt.   In industrial practice, a large number of process and quality control tasks are performed visually by employees or with the aid of camera systems. By using artificial intelligence, the programming effort and thus the implementation of camera systems can be made more efficient. Pre-trained ^neural networks can be used for image analysis. The application of these networks to new tasks is called transfer learning.
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5

Vaishnavi, J., and V. Narmatha. "Novel Transfer Learning Attitude for Automatic Video Captioning Using Deep Learning Models." Indian Journal Of Science And Technology 15, no. 43 (November 20, 2022): 2325–35. http://dx.doi.org/10.17485/ijst/v15i43.1846.

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6

Cao, Bin, Sinno Jialin Pan, Yu Zhang, Dit-Yan Yeung, and Qiang Yang. "Adaptive Transfer Learning." Proceedings of the AAAI Conference on Artificial Intelligence 24, no. 1 (July 3, 2010): 407–12. http://dx.doi.org/10.1609/aaai.v24i1.7682.

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Transfer learning aims at reusing the knowledge in some source tasks to improve the learning of a target task. Many transfer learning methods assume that the source tasks and the target task be related, even though many tasks are not related in reality. However, when two tasks are unrelated, the knowledge extracted from a source task may not help, and even hurt, the performance of a target task. Thus, how to avoid negative transfer and then ensure a "safe transfer" of knowledge is crucial in transfer learning. In this paper, we propose an Adaptive Transfer learning algorithm based on Gaussian Processes (AT-GP), which can be used to adapt the transfer learning schemes by automatically estimating the similarity between a source and a target task. The main contribution of our work is that we propose a new semi-parametric transfer kernel for transfer learning from a Bayesian perspective, and propose to learn the model with respect to the target task, rather than all tasks as in multi-task learning. We can formulate the transfer learning problem as a unified Gaussian Process (GP) model. The adaptive transfer ability of our approach is verified on both synthetic and real-world datasets.
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7

Yu, Zhengxu, Dong Shen, Zhongming Jin, Jianqiang Huang, Deng Cai, and Xian-Sheng Hua. "Progressive Transfer Learning." IEEE Transactions on Image Processing 31 (2022): 1340–48. http://dx.doi.org/10.1109/tip.2022.3141258.

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8

Renta-Davids, Ana-Inés, José-Miguel Jiménez-González, Manel Fandos-Garrido, and Ángel-Pío González-Soto. "Transfer of learning." European Journal of Training and Development 38, no. 8 (August 27, 2014): 728–44. http://dx.doi.org/10.1108/ejtd-03-2014-0026.

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Purpose – This paper aims to analyse transfer of learning to workplace regarding to job-related training courses. Training courses analysed in this study are offered under the professional training for employment framework in Spain. Design/methodology/approach – During the training courses, trainees completed a self-reported survey of reasons for participation (time 1 data collection, N = 447). Two months after training, a second survey was sent to the trainees by email (time 2 data collection, N = 158). Factor analysis, correlations and multiple hierarchical regressions were performed. Findings – The results of this study demonstrate the importance of training relevance and training effectiveness in transfer of training. Results indicated that relevance, the extent training courses were related to participant’s workplace activities and professional development, positively influences transfer of training. Effectiveness, training features which facilitated participants to acquire knowledge and skills, also has a significantly positive influence in transfer of training. Motivation to participate and learning-conducive workplace features also have a positive influence in transfer of training. Originality/value – This study contributes to the understanding of transfer of learning in work-related training programmes by analysing the factors that influence transfer of learning back to the workplace. The study has practical implication for training designers and education providers to enhance work-related training in the context of the Professional Training for Employment Subsystem in Spain.
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9

Tetzlaff, Linda. "Transfer of learning." ACM SIGCHI Bulletin 17, SI (May 1986): 205–10. http://dx.doi.org/10.1145/30851.275631.

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10

Koçer, Barış, and Ahmet Arslan. "Genetic transfer learning." Expert Systems with Applications 37, no. 10 (October 2010): 6997–7002. http://dx.doi.org/10.1016/j.eswa.2010.03.019.

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11

Tetzlaff, Linda. "Transfer of learning." ACM SIGCHI Bulletin 18, no. 4 (April 1987): 205–10. http://dx.doi.org/10.1145/1165387.275631.

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12

Zhao, Peilin, Steven C. H. Hoi, Jialei Wang, and Bin Li. "Online Transfer Learning." Artificial Intelligence 216 (November 2014): 76–102. http://dx.doi.org/10.1016/j.artint.2014.06.003.

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13

SATO, Hirokazu, Ryoji OTSU, Yonghoon JI, Hiromitsu FUJII, and Hitoshi KONO. "Automatic Transfer Rate Estimation for Transfer Learning in Reinforcement Learning." Proceedings of JSME annual Conference on Robotics and Mechatronics (Robomec) 2020 (2020): 2A2—J03. http://dx.doi.org/10.1299/jsmermd.2020.2a2-j03.

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14

Gardie, Birhanu, Smegnew Asemie, Kasahun Azezew, and Zemedkun Solomon. "Potato Plant Leaf Diseases Identification Using Transfer Learning." Indian Journal of Science and Technology 15, no. 4 (January 25, 2022): 158–65. http://dx.doi.org/10.17485/ijst/v15i4.1235.

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15

Chaithanya, A. Sainath, and M. Rachana. "Identification of Diseased Papaya Leaf through Transfer Learning." Indian Journal Of Science And Technology 16, no. 48 (December 28, 2023): 4676–87. http://dx.doi.org/10.17485/ijst/v16i48.2690.

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16

Velada, Raquel, António Caetano, Reid Bates, and Ed Holton. "Learning transfer – validation of the learning transfer system inventory in Portugal." Journal of European Industrial Training 33, no. 7 (August 28, 2009): 635–56. http://dx.doi.org/10.1108/03090590910985390.

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17

Gui, Lin, Ruifeng Xu, Qin Lu, Jiachen Du, and Yu Zhou. "Negative transfer detection in transductive transfer learning." International Journal of Machine Learning and Cybernetics 9, no. 2 (February 9, 2017): 185–97. http://dx.doi.org/10.1007/s13042-016-0634-8.

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18

Rani, S. V. Jansi. "Plant Disease Detection using Transfer Learning in Precision Agriculture." AMBIENT SCIENCE 9, no. 3 (November 2022): 34–39. http://dx.doi.org/10.21276/ambi.2022.09.3.ta02.

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19

Imran, Sheik, and Pradeep N. "A Comprehensive Review on Machine Learning and Transfer Learning Approaches in Liver Tumor Classification." International Journal of Science and Research (IJSR) 13, no. 7 (July 5, 2024): 1034–38. http://dx.doi.org/10.21275/sr24723105503.

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20

Hurt, Brian, Meagan A. Rubel, Evan M. Masutani, Kathleen Jacobs, Lewis Hahn, Michael Horowitz, Seth Kligerman, and Albert Hsiao. "Radiologist-supervised Transfer Learning." Journal of Thoracic Imaging 37, no. 2 (October 28, 2021): 90–99. http://dx.doi.org/10.1097/rti.0000000000000618.

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21

Ford, J. Kevin. "Defining Transfer of Learning." Adult Learning 5, no. 4 (March 1994): 22–30. http://dx.doi.org/10.1177/104515959400500412.

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22

Steenhuis, Harm-Jan, and Erik J. De Bruijn. "Technology Transfer and Learning." Technology Analysis & Strategic Management 14, no. 1 (March 2002): 57–66. http://dx.doi.org/10.1080/09537320220125883.

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23

Hu, Junlin, Jiwen Lu, Yap-Peng Tan, and Jie Zhou. "Deep Transfer Metric Learning." IEEE Transactions on Image Processing 25, no. 12 (December 2016): 5576–88. http://dx.doi.org/10.1109/tip.2016.2612827.

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24

Larsen-Freeman, Diane. "Transfer of Learning Transformed." Language Learning 63 (February 13, 2013): 107–29. http://dx.doi.org/10.1111/j.1467-9922.2012.00740.x.

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25

Liu, Xiaobo. "Ensemble Inductive Transfer Learning." Journal of Fiber Bioengineering and Informatics 8, no. 1 (June 2015): 105–15. http://dx.doi.org/10.3993/jfbi03201510.

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26

Ashburner, Jill, Jenny Ziviani, Sylvia Rodger, Elizabeth A. Hinder, Linda Cartmill, Jessica White, and Sandy Vickerstaff. "Improving Transfer of Learning." Journal of Continuing Education in the Health Professions 35, no. 4 (2015): 270–77. http://dx.doi.org/10.1097/ceh.0000000000000000.

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27

Hu, Xuegang, Jianhan Pan, Peipei Li, Huizong Li, Wei He, and Yuhong Zhang. "Multi-bridge transfer learning." Knowledge-Based Systems 97 (April 2016): 60–74. http://dx.doi.org/10.1016/j.knosys.2016.01.016.

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28

Karbalayghareh, Alireza, Xiaoning Qian, and Edward R. Dougherty. "Optimal Bayesian Transfer Learning." IEEE Transactions on Signal Processing 66, no. 14 (July 15, 2018): 3724–39. http://dx.doi.org/10.1109/tsp.2018.2839583.

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29

Liu, Xiaobo, Zhentao Liu, Guangjun Wang, Zhihua Cai, and Harry Zhang. "Ensemble Transfer Learning Algorithm." IEEE Access 6 (2018): 2389–96. http://dx.doi.org/10.1109/access.2017.2782884.

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30

Hassan Mahmud, M. M. "On universal transfer learning." Theoretical Computer Science 410, no. 19 (April 2009): 1826–46. http://dx.doi.org/10.1016/j.tcs.2009.01.013.

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31

Chun-Wei Seah, Ivor W. Tsang, and Yew-Soon Ong. "Transfer Ordinal Label Learning." IEEE Transactions on Neural Networks and Learning Systems 24, no. 11 (November 2013): 1863–76. http://dx.doi.org/10.1109/tnnls.2013.2268541.

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32

Ding, Zhengming, Ming Shao, and Yun Fu. "Incomplete Multisource Transfer Learning." IEEE Transactions on Neural Networks and Learning Systems 29, no. 2 (February 2018): 310–23. http://dx.doi.org/10.1109/tnnls.2016.2618765.

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33

Wang, Longhan, Yifan Sun, and Xiangdong Zhang. "Quantum Adversarial Transfer Learning." Entropy 25, no. 7 (July 20, 2023): 1090. http://dx.doi.org/10.3390/e25071090.

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Adversarial transfer learning is a machine learning method that employs an adversarial training process to learn the datasets of different domains. Recently, this method has attracted attention because it can efficiently decouple the requirements of tasks from insufficient target data. In this study, we introduce the notion of quantum adversarial transfer learning, where data are completely encoded by quantum states. A measurement-based judgment of the data label and a quantum subroutine to compute the gradients are discussed in detail. We also prove that our proposal has an exponential advantage over its classical counterparts in terms of computing resources such as the gate number of the circuits and the size of the storage required for the generated data. Finally, numerical experiments demonstrate that our model can be successfully trained, achieving high accuracy on certain datasets.
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34

Lavine, Barry K., Karl S. Booksh, and Sharon L. Neal. "Transductive and Transfer Learning." Journal of Experimental and Theoretical Analyses 2, no. 2 (June 14, 2024): 56–57. http://dx.doi.org/10.3390/jeta2020005.

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35

Kawalilak, Colleen Anne. "Successful Transfer of Learning." Canadian Journal for the Study of Adult Education 25, no. 1 (November 30, 2012): 75–76. http://dx.doi.org/10.56105/cjsae.v25i1.359.

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36

Silva, Felipe Leno da, and Anna Helena Reali Costa. "Transfer Learning for Multiagent Reinforcement Learning Systems." Synthesis Lectures on Artificial Intelligence and Machine Learning 15, no. 3 (May 27, 2021): 1–129. http://dx.doi.org/10.2200/s01091ed1v01y202104aim049.

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37

Rajkumar, R., Arnav Kaushal, and Aishik Saha. "Accelerating Machine Learning Research Using Transfer Learning." Indian Journal of Computer Science 3, no. 2 (April 1, 2018): 7. http://dx.doi.org/10.17010/ijcs/2018/v3/i2/123212.

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38

Tamaazousti, Youssef, Herve Le Borgne, Celine Hudelot, Mohamed-El-Amine Seddik, and Mohamed Tamaazousti. "Learning More Universal Representations for Transfer-Learning." IEEE Transactions on Pattern Analysis and Machine Intelligence 42, no. 9 (September 1, 2020): 2212–24. http://dx.doi.org/10.1109/tpami.2019.2913857.

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39

Lewis, Kyle, Donald Lange, and Lynette Gillis. "Transactive Memory Systems, Learning, and Learning Transfer." Organization Science 16, no. 6 (December 2005): 581–98. http://dx.doi.org/10.1287/orsc.1050.0143.

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40

Iqbal, Muhammad Shahid, Bin Luo, Tamoor Khan, Rashid Mehmood, and Muhammad Sadiq. "Heterogeneous transfer learning techniques for machine learning." Iran Journal of Computer Science 1, no. 1 (January 9, 2018): 31–46. http://dx.doi.org/10.1007/s42044-017-0004-z.

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41

Zhang, Quanqi, Chengwei Wu, Haoyu Tian, Yabin Gao, Weiran Yao, and Ligang Wu. "Safety reinforcement learning control via transfer learning." Automatica 166 (August 2024): 111714. http://dx.doi.org/10.1016/j.automatica.2024.111714.

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42

Han, Jiwoon, and Daeil Kwon. "Transfer Learning-based Adaptive Diagnosis for Power Plants under Varying Operating Conditions." PHM Society European Conference 8, no. 1 (June 27, 2024): 6. http://dx.doi.org/10.36001/phme.2024.v8i1.4096.

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Transfer learning is a method that transfers knowledge learned from a source domain to a similar target domain to improve learning. In power plants, obtaining sufficient anomaly data is difficult due to the characteristics of the systems. Transfer learning enables learning with only a small amount of data from the target domain by using a model trained in a similar domain. By applying transfer learning, models developed for one power plant can be expanded and used in other power plants where available data are limited. Using actual data from an operating combined-cycle power plant, an anomaly diagnosis model was developed and tested. Its applicability to different operating conditions and anomaly cases was evaluated through transfer learning. The fine-tuned pre-trained model was effectively adapted with limited target domain data. Transfer learning was applied despite the limitations of data and distribution differences. The expandability of anomaly diagnosis models to different power plant systems was demonstrated by applying transfer learning.
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43

Hua, Jiang, Liangcai Zeng, Gongfa Li, and Zhaojie Ju. "Learning for a Robot: Deep Reinforcement Learning, Imitation Learning, Transfer Learning." Sensors 21, no. 4 (February 11, 2021): 1278. http://dx.doi.org/10.3390/s21041278.

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Dexterous manipulation of the robot is an important part of realizing intelligence, but manipulators can only perform simple tasks such as sorting and packing in a structured environment. In view of the existing problem, this paper presents a state-of-the-art survey on an intelligent robot with the capability of autonomous deciding and learning. The paper first reviews the main achievements and research of the robot, which were mainly based on the breakthrough of automatic control and hardware in mechanics. With the evolution of artificial intelligence, many pieces of research have made further progresses in adaptive and robust control. The survey reveals that the latest research in deep learning and reinforcement learning has paved the way for highly complex tasks to be performed by robots. Furthermore, deep reinforcement learning, imitation learning, and transfer learning in robot control are discussed in detail. Finally, major achievements based on these methods are summarized and analyzed thoroughly, and future research challenges are proposed.
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44

Kono, Hitoshi, Yuto Sakamoto, Yonghoon Ji, and Hiromitsu Fujii. "Automatic Transfer Rate Adjustment for Transfer Reinforcement Learning." International Journal of Artificial Intelligence & Applications 11, no. 6 (November 30, 2020): 47–54. http://dx.doi.org/10.5121/ijaia.2020.11605.

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This paper proposes a novel parameter for transfer reinforcement learning to avoid over-fitting when an agent uses a transferred policy from a source task. Learning robot systems have recently been studied for many applications, such as home robots, communication robots, and warehouse robots. However, if the agent reuses the knowledge that has been sufficiently learned in the source task, deadlock may occur and appropriate transfer learning may not be realized. In the previous work, a parameter called transfer rate was proposed to adjust the ratio of transfer, and its contribution include avoiding dead lock in the target task. However, adjusting the parameter depends on human intuition and experiences. Furthermore, the method for deciding transfer rate has not discussed. Therefore, an automatic method for adjusting the transfer rate is proposed in this paper using a sigmoid function. Further, computer simulations are used to evaluate the effectiveness of the proposed method to improve the environmental adaptation performance in a target task, which refers to the situation of reusing knowledge.
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45

Rezapour, Mahdi, and Khaled Ksaibati. "Convolutional Neural Network for Roadside Barriers Detection: Transfer Learning versus Non-Transfer Learning." Signals 2, no. 1 (February 1, 2021): 72–86. http://dx.doi.org/10.3390/signals2010007.

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Increasingly more governmental organizations in the U.S. have started to implement artificial intelligence to enhance the asset management process with an objective of controlling the costs of data collection. To help the Wyoming Department of Transportation (WYDOT) to automate the data collections process, related to various assets in the state, an automated assets management data collection was proposed. As an example, the automated traffic barriers asset dataset would collect geometric characteristics, and barriers’ materials’ conditions, e.g., being rusty or not. The information would be stored and accessed for asset-management-decision-making and optimization process to fulfill various objectives such as traffic safety improvement, or assets’ enhancement. For instance, the State of Wyoming has more than a million feet of roadside barriers, worth more than 100 million dollars. One-time collection of various characteristics of those barriers has cost the state more than half a million dollars. Thus, this study, as a first step for comprehensive data collection, proposed a novel approach in identification of roadside barrier types. Pre-trained inception v3, denseNet 121, and VGG 19 were implemented in this study. Transfer learning was used as there were only 250 images for training of the dataset for each category. For that method, the topmost layers were removed, along with adding two more new layers while freezing the remaining layers. This study achieved an accuracy of 97% by the VGG 19 network, training only the few last layers of the model along with adding two dense layers for top layers. The results indicated that although there are not enough observations related to traffic barrier images, a transfer learning application could be considered in data collection. A simple architecture non-transfer model was also implemented. This model achieved an accuracy of 85%, being better that the two other transfer learning techniques. It should be reiterated that although non-transfer learning technique outperformed inception and denseNet networks, it comes short significantly when it come to the VGG network.
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46

Ali, W., and S. Kolyubin. "EMG-Based Grasping Force Estimation for Robot Skill Transfer Learning." Nelineinaya Dinamika 18, no. 5 (2022): 0. http://dx.doi.org/10.20537/nd221221.

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In this study, we discuss a new machine learning architecture, the multilayer preceptron-random forest regressors pipeline (MLP-RF model), which stacks two ML regressors of different kinds to estimate the generated gripping forces from recorded surface electromyographic activity signals (EMG) during a gripping task. We evaluate our proposed approach on a publicly available dataset, putEMG-Force, which represents a sEMG-Force data profile. The sEMG signals were then filtered and preprocessed to get the features-target data frame that will be used to train the proposed ML model. The proposed ML model is a pipeline of stacking 2 different natural ML models; a random forest regressor model (RF regressor) and a multiple layer perceptron artificial neural network (MLP regressor). The models were stacked together, and the outputs were penalized by a Ridge regressor to get the best estimation of both models. The model was evaluated by different metrics; mean squared error and coefficient of determination, or $r^{2}$ score, to improve the model prediction performance. We tuned the most significant hyperparameters of each of the MLP-RF model components using a random search algorithm followed by a grid search algorithm. Finally, we evaluated our MLP-RF model performance on the data by training a recurrent neural network consisting of 2 LSTM layers, 2 dropouts, and one dense layer on the same data (as it is the common approach for problems with sequential datasets) and comparing the prediction results with our proposed model. The results show that the MLP-RF outperforms the RNN model.
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47

Fawaiq, Mohammad Nur, Ema Utami, and Dhani Ariatmanto. "Rice Plant Disease Detection with Data Augmentation Using Transfer Learning." International Journal of Research Publication and Reviews 4, no. 4 (April 8, 2023): 2195–99. http://dx.doi.org/10.55248/gengpi.2023.4.4.35530.

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48

Son, Ji Y., and Robert L. Goldstone. "Fostering general transfer with specific simulations." Pragmatics and Cognition 17, no. 1 (February 18, 2009): 1–42. http://dx.doi.org/10.1075/pc.17.1.01son.

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Science education faces the difficult task of helping students understand and appropriately generalize scientific principles across a variety of superficially dissimilar specific phenomena. Can cognitive technologies be adapted to benefit both learning specific domains and generalizable transfer? This issue is examined by teaching students complex adaptive systems with computer-based simulations. With a particular emphasis on fostering understanding that transfers to dissimilar phenomena, the studies reported here examine the influence of different descriptions and perceptual instantiations of the scientific principle of competitive specialization. Experiment 1 examines the role of intuitive descriptions to concrete ones, finding that intuitive descriptions leads to enhanced domain-specific learning but also deters transfer. Experiment 2 successfully alleviated these difficulties by combining intuitive descriptions with idealized graphical elements. Experiment 3 demonstrates that idealized graphics are more effective than concrete graphics even when unintuitive descriptions are applied to them. When graphics are concrete, learning and transfer largely depend on the particular description. However, when graphics are idealized, a wider variety of descriptions results in levels of learning and transfer similar to the best combination involving concrete graphics. Although computer-based simulations can be effective for learning that transfers, designing effective simulations requires an understanding of concreteness and idealization in both the graphical interface and its description.
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49

Yi, Wang. "The Influence of Shandong dialect on English learning." Communications in Humanities Research 10, no. 1 (October 31, 2023): 93–98. http://dx.doi.org/10.54254/2753-7064/10/20231262.

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Phonologythe material shell of languagehas its own peculiarities because language structures and realizations vary. Behaviorist phonological theory implies that prior phonological patterns interfere with second-language communication. Learners inadvertently transfer their native language pronunciation to foreign language acquisition. The transfer is a psychological phrase that used to refer primarily to the influence of former learning on subsequent learning but now refers to the influence of one type of learning on another. Positive and negative transfers exist. English is Indo-European, while Chinese is Sino-Tibetan. distinct language families mean distinct phonological intonation systems and pronunciation patterns, therefore negative transfer of phonological learning is inevitable. Chinese students learn various dialects, each with its own system, and these dialects deeply affect English phonological intonation learning. This paper examines the transfer effect of the Shandong dialect on English phonology and the negative transfer of dialects to English intonation learning. The phonological system differs in terms of consonant parts and pronunciation methods, and the intonation system differs in tone, intonation, stress, and rhythm.
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50

Hung, Woei. "Problem-Based Learning: A Learning Environment for Enhancing Learning Transfer." New Directions for Adult and Continuing Education 2013, no. 137 (March 2013): 27–38. http://dx.doi.org/10.1002/ace.20042.

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