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Journal articles on the topic 'Electronics'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 March 2025

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1

Badilla, Gustavo López, Juan Abraham Pérez Ramos, Joaquín Díaz Algara, and Marco Antonio Rodríguez Vera. "Electronic Systems Damaged by Corrosion in The Electronics Industry of Mexicali." Paripex - Indian Journal Of Research 3, no. 6 (January 15, 2012): 77–79. http://dx.doi.org/10.15373/22501991/june2014/24.

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2

Ramdana, Ilham. "Company and Brand Rebranding: A Study on the Electronic Retail Industry." Jurnal Audience 5, no. 1 (September 11, 2022): 42–55. http://dx.doi.org/10.33633/ja.v5i1.5339.

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This study analyzes the rebranding process in the case of a brand change from White Brown Electronics to Informa Electronics. The method used is descriptive method with a qualitative approach. Sources of data obtained through library research and field studies in the form of observations and interviews. The research was conducted at Informa Electronics Lving World Alam Sutera in Tangerang City and the object of the research was how marketing communication strategies for electronic products at Informa Electronics. The data is analyzed through the data reduction or data sorting stage, then the data is presented or displayed, and finally concluded according to the research problem. The results show that Informa Electronics has succeeded in making people and customers believe and continue to shop at Informa Electronics. The conclusions obtained from the research are: Informa Electronics in the process of rebranding a brand involves various aspects, namely, benefit description, association, distinction, awareness or brand identity, brand image and create trust. Informa Electronics also uses various promotional media, both online and offline promotional media, to improve their marketing communication strategies. These various things were carried out in order to increase the knowledge of the public and customers about Informa Electronics so as to generate feedback, namely by buying electronic products at Informa Electronics. Informa Electronics also uses various promotional media, both online and offline promotional media, to improve their marketing communication strategies. These various things were carried out in order to increase the knowledge of the public and customers about Informa Electronics so as to generate feedback, namely by buying electronic products at Informa Electronics. Informa Electronics also uses various promotional media, both online and offline promotional media, to improve their marketing communication strategies. These various things were carried out in order to increase the knowledge of the public and customers about Informa Electronics so as to generate feedback, namely by buying electronic products at Informa Electronics.
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3

FURUTA, Kiyoto. "Activities in Electronic and Electronics Industry." Journal of The Institute of Electrical Engineers of Japan 126, no. 3 (2006): 146–49. http://dx.doi.org/10.1541/ieejjournal.126.146.

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4

Chen, Sen, and Jing Liu. "Liquid metal printed electronics towards ubiquitous electrical engineering." Japanese Journal of Applied Physics 61, SE (April 5, 2022): SE0801. http://dx.doi.org/10.35848/1347-4065/ac5761.

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Abstract Conventional electronic manufacturers are generally not easily accessible due to complicated procedures, time, material and energy consuming, and may generate potential pollution to the environment. From an alternative, liquid metal printed electronics to quickly fabricate electronic circuits and functional devices were proposed a decade before. To promote the further development and application of liquid metal printed electronics, this review aims to summarize and analyze the progress of liquid metal printed electronics from three aspects, namely electronic inks, printing technology and applications. Then, we will discuss the challenges and opportunities for further development of liquid metal printed electronics from several aspects including material modification, technological innovation, equipment upgrading and potential applications. It is expected that liquid metal printed electronics allow one to make electronics at anytime, anywhere at low cost which indicates the coming of a new era of ubiquitous electrical engineering.
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Yu, Cunjiang. "(Invited) rubbery Electronics to Seamlessly Integrate with Human Body." ECS Meeting Abstracts MA2023-01, no. 34 (August 28, 2023): 1902. http://dx.doi.org/10.1149/ma2023-01341902mtgabs.

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Electronics that can seamlessly integrate with human body could have significant impact in medical diagnostic, therapeutics. However, seamless integration is a grand challenge because of the distinct nature between electronics and human body. Conventional electronics are rigid and planar, made out of rigid materials. Human body are soft, deformable and curvilinear, comprised of biological materials, organs and tissues. This talk will introduce our solution to address the challenge through the invention of a new class of electronics, namely rubbery electronics. Rubbery electronics is constructed all based on elastic rubber electronic materials of semiconductors, conductors and dielectrics, which possesses tissue-like softness and mechanical stretchability to allow seamless integration with soft deformable tissues and organs. Rubbery electronic materials (particularly semiconductors) and device innovations set the foundation for rubbery electronics. This presentation will feature the development and understanding of rubbery semiconductors, rubbery transistors, integrated electronics, sensors and bioelectronics. In addition, rubbery electronics enabled functional systems will also be demonstrated. As a platform technology, rubbery electronics opens up numerous opportunities for many different fields such as healthcare, robotics, human-machine interfaces, artificial intelligence.
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Dandi Ramadhan, Muhammad, Iqbal Valiri Zulfikar, and Popy Rufaidah. "Analisis Rantai Nilai Industri Ritel Elektronik (Studi Kasus: PT. Electronic City Indonesia Tbk)." Jurnal Manajemen dan Organisasi 14, no. 3 (October 5, 2023): 287–96. http://dx.doi.org/10.29244/jmo.v14i3.47168.

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This research aims to produce a map of the industrial value chain at PT. Electronic City Indonesia Tbk uses the industrial value chain analysis model. Researchers use the case study method, an empirical investigation method that examines a recent case or phenomenon in depth and reality, especially when the boundary between wonder and context is unclear. The subject of this research is PT. Electronic City Indonesia Tbk. The results of the research yield information on a list of companies engaged in the Indonesian electronics retail industry, a list of companies as product suppliers for the Indonesian retail sector where they are part of the product manufacturer and assembler industry (PT. Sony Electronics Indonesia, PT. Samsung Electronics Indonesia, PT. Sharp Electronics Indonesia, PT. LG Electronics Indonesia, and others) and a list of companies that are suppliers to the product assembly industry in Indonesia located outside Indonesia (Samsung Electronic, Sharp Corporation, LG Group, and Sony Corporation and others). The value chain of the e-commerce industry conducted by PT Electronic City Indonesia Tbk is relatively simple because it only has links with producers/suppliers and end consumers. There are four actors in the value chain of the retail electronics industry: component or raw material supplier companies, manufacturing companies, retail electronics companies, and end consumers. PT. Electronic City Indonesia Tbk has no products produced under its brand and does not carry out a value-added process. This can be a threat if manufacturers or suppliers experience production problems because it will hinder product sales in the retail electronics industry.
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7

Balakumar Muniandi. "Bio-Electronics Interface between Electronics and Biological Systems for Healthcare Applications." Power System Technology 48, no. 1 (April 27, 2024): 698–714. http://dx.doi.org/10.52783/pst.329.

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The intersection of electronics and biology has led to the emergence of bio-electronics interfaces, which hold tremendous potential for revolutionizing healthcare applications. These interfaces facilitate seamless communication between electronic devices and biological systems, enabling a range of diagnostic, therapeutic, and monitoring capabilities with unprecedented precision and efficiency.This paper provides a comprehensive overview of the recent advancements in bio-electronics interfaces and their diverse applications in healthcare. The fundamental principles underlying the integration of electronics with biological systems, including the design and fabrication of bio-compatible materials, signal transduction mechanisms, and biointegration strategies are discussed. [1] The paper discusses specific healthcare applications enabled by bio-electronics interfaces, such as bio-sensing for disease diagnosis, neural interfaces for brain-machine communication and prosthetics, bio-electronic implants for targeted drug delivery and neuromodulation, and wearable devices for continuous health monitoring. We also examine the challenges and opportunities associated with the development and implementation of bio-electronics interfaces in healthcare settings. These challenges include biocompatibility issues, signal interference, power management, data security, and regulatory considerations. However, rapid advancements in materials science, microfabrication techniques, wireless communication, and machine learning are driving innovation and overcoming these hurdles. We highlight the potential of bio-electronics interfaces to transform personalized medicine by enabling real-time monitoring of physiological parameters, early detection of diseases, and personalized therapeutic interventions tailored to individual patients' needs. By integrating electronic devices with biological systems at the molecular, cellular, and organismal levels, bio-electronics interfaces have the potential to revolutionize healthcare delivery, improve patient outcomes, and enhance quality of life.
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Amalia Dewi, Rizky, and Budi Santoso. "Legal Aspects of Electronic Signatures In Indonesia." Eduvest - Journal of Universal Studies 2, no. 10 (October 29, 2022): 2140–48. http://dx.doi.org/10.36418/eduvest.v2i10.627.

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Study this aim for research and analyze aspect law sign hand electronic based on perspective law positive in Indonesia. Study this use method study juridical normative, with using secondary data, research conducted with use studies bibliography. Approach analysis used is descriptive analytical. Based on results study is known that sign hand electronics in essence is something sign agreement in form working electronics as form the agreement of the parties who make and carry out agreement electronics. Making sign hand electronic by agency sign hand specified electronics and mechanisms in regulation applicable legislation. Condition valid agreement electronic has determined in Article 53 paragraph 2 and Article 54 paragraph 1 and 2 of the Government Regulation concerning Organizer System and Transaction Electronic
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Amalia Dewi, Rizky, and Budi Santoso. "Legal Aspects of Electronic Signatures In Indonesia." Eduvest - Journal of Universal Studies 2, no. 10 (October 29, 2022): 2140–48. http://dx.doi.org/10.59188/eduvest.v2i10.627.

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Study this aim for research and analyze aspect law sign hand electronic based on perspective law positive in Indonesia. Study this use method study juridical normative, with using secondary data, research conducted with use studies bibliography. Approach analysis used is descriptive analytical. Based on results study is known that sign hand electronics in essence is something sign agreement in form working electronics as form the agreement of the parties who make and carry out agreement electronics. Making sign hand electronic by agency sign hand specified electronics and mechanisms in regulation applicable legislation. Condition valid agreement electronic has determined in Article 53 paragraph 2 and Article 54 paragraph 1 and 2 of the Government Regulation concerning Organizer System and Transaction Electronic
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10

Liu, Chenchen. "Organic Electronics: Material Innovations, Synthesis Strategies, and Applications as Flexible Electronics." Highlights in Science, Engineering and Technology 106 (July 16, 2024): 332–37. http://dx.doi.org/10.54097/zn612t89.

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Organic electronics has emerged as a transformative field in materials science, revolutionizing the development of flexible, lightweight, and cost-effective electronic components. Utilizing carbon-based organic small molecules and polymers, this technology diverges significantly from traditional inorganic electronic materials, offering unique advantages in terms of flexibility and processability. This paper provides a comprehensive review of the advancements within the field of organic electronics, focusing on essential materials such as conductive polymers, small molecule semiconductors, and organic photovoltaic materials. The paper highlights various production methods that enable large-scale and cost-effective manufacturing and explores innovations in chemical synthesis that enhance device performance and stability. Furthermore, it addresses the integration of these materials into practical applications, illustrating their potential to significantly impact the electronic device market. Despite the progress in material development, challenges remain in material durability, efficiency, and integration into existing systems. In conclusion, the field of organic electronics represents a dynamic and evolving area of materials science that holds significant promise for transforming the landscape of electronic devices.
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11

Pavlenko, Olha. "Research into professional training of elecronics engineers in Ukraine and the USA: basic concepts." Continuing Professional Education: Theory and Practice, no. 3-4 (2018): 57–61. http://dx.doi.org/10.28925/1609-8595.2018.3-4.5761.

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The article explores the impact of the rapid development of electronic devices and systems in the world, in particular in the USA on setting the new challenges for Ukrainian engineering universities to attract advanced experience in training Electronics Engineering professionals. Since there are differences in the interpretation of a number of concepts in the area of Electronic Engineering in Ukrainian education as compared to the US, the article examines the relationship between the terms «electrical» and «electronic engineering», defines and compares such concepts as «electronics specialist», «electronics engineer», «professional training of electronics specialists», and «US higher education institution» in Ukrainian and US educational and scientific settings. The article advances our understanding of professional occupation outlook of a specialist in as a professional, who studies the field of electronic engineering, and is involved in the study, design, development or testing of electronic components, circuits and systems for commercial, industrial, military or scientific use using knowledge of electronic theory and its properties. By comparing Ukrainian and US higher education institutions in terms of their views and approaches to training electronics engineers and mutual understanding of Electronic Engineering as an electrical engineering discipline, together these findings provide important insights into application of engineering training practices into Ukrainian tertiary engineering settings, give grounds for a further research into pedagogical theory as well as organization and network of higher education institutions for training electronics engineers in order to implement the best practices in higher education institutions of Ukraine.
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12

Vickery, Lindsay. "The Western Edge: some recent electronic music from Western Australia." Organised Sound 6, no. 1 (April 2001): 69–74. http://dx.doi.org/10.1017/s1355771801001108.

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A survey is presented of developments in recent Western Australian electronic music, focusing on the geographical influence on local composers' work. The article follows specific cases of practitioners in the fields of Sound Art (Alan Lamb and Hannah Clemen), Live Electronics (Cathie Travers and the electronic music quartet Magnetic Pig), Interactive Electronics (Jonathan Mustard and Lindsay Vickery) and Noise/Lo Fi Electronics (Cat Hope and Lux Mammoth).
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13

Rahman, Syaifur. "Pelatihan Elektronika Dasar Bagi Siswa Sekolah Menengah Atas di Wilayah Kalimantan Barat." Jurnal Pengabdi 4, no. 2 (October 28, 2021): 185. http://dx.doi.org/10.26418/jplp2km.v4i2.48106.

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The community service in the form of electronics training aims to introduce the field of electronics to high school students in several districts in West Kalimantan.This electronics training is carried out to increase the knowledge of students in the field of electronics to increase their interest in studying at the Department of Electrical Engineering,Tanjungpura University.There are five schools targeted for the training, namely: MAN IC Sambas, SMKN 1 Sambas, SMAN 1 Siantan, SMAN 1 Paloh Sambas and SMKN 1 Mandor Landak.The method used is class discussion and practice by directly involving students to jointly assemble electronic circuits using electronic modules that have been made.During the training activities the students were very enthusiastic about participating in the training and this was shown by many students who wanted to try assembling electronic circuits with the provided electronic modules.Furthermore, the electronic modules were handed over to the school in order to motivate students to try to learn other electronic circuits.
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14

Jones-Imhotep, Edward. "Icons and Electronics." Historical Studies in the Natural Sciences 38, no. 3 (2008): 405–50. http://dx.doi.org/10.1525/hsns.2008.38.3.405.

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In the late 1950s, a wide-ranging debate erupted over the seemingly innocuous question of how transistors——the revolutionary new electronic devices——should be drawn. By forcing a break in the long-standing traditions of electronic drawing, transistors generated a crisis in the ontology of circuit diagrams, forcing a choice between representations that emphasized form and those that stressed function. This paper explores what was at stake in that mid-century debate over visual culture. It tracks one function-based symbol through concerns about auto-comprehension, visual communication, and electronic reliability to see how transistor symbols formed crucial sites for articulating the meanings of material devices and their relationship to the wider populations of electronic entities, especially vacuum tubes. In doing so, the article shifts the emphasis in the history of electronics from material to visual culture, recasting our understanding of postwar electronics as a history of drawings as well as devices.
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15

Chi, Aobing, Enming Zhang, and Xu Hang. "Development of nanomaterials in flexible electronics." Highlights in Science, Engineering and Technology 43 (April 14, 2023): 40–49. http://dx.doi.org/10.54097/hset.v43i.7404.

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Flexible electronics, with its excellent flexibility, leading-edge and lightweight, has become a frontier technology capability in the field of electronics, which integrates well with the characteristics of nanomaterials for applications in various disciplines such as sensors, information, medical, and energy. This paper systematically summarizes the main structures of flexible electronics featuring flexible substrates with their outstanding flexibility as well as mechanical and electrical properties. Afterwards, it delves into the four major properties of nanomaterials along with their extensive applications aboard flexible electronics. In particular, the development applications of carbon nanotube films in sensors and electronic devices by means of their great flexibility and electrical conductivity are mainly outlined. Then the practical applications of graphene in the domain of electronic displayer through its superior heat dissipation are introduced. In the final part, an exploration is made on how the advantages of flexible electronics and nanomaterials can be further used in frontier fields such as aerospace, smart medicine, and automated science if we combine them more effectively. However, as an emerging field, the development process of flexible electronics is still fraught with challenges. Two major challenges are still facing the field: mechanics, packaging, and cost. There is a long way to go for flexible electronics combined with nanomaterials, which can open numerous possibilities for electronic technology.
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16

Aly. "Electronic Design Automation Using Object Oriented Electronics." American Journal of Engineering and Applied Sciences 3, no. 1 (January 1, 2010): 121–27. http://dx.doi.org/10.3844/ajeassp.2010.121.127.

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17

Seliverstova, N. S. "Structural shifts in the Russian electronics industry." Russian Journal of Industrial Economics 17, no. 1 (February 1, 2024): 67–75. http://dx.doi.org/10.17073/2072-1633-2024-1-1255.

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The object of the study is the electronics industry of Russia and its significant structural changes which took place in 2015–2023. The author has points out the general features of electronics industry in Russia, identifies the basic formed structural shifts in the electronics industry and the relationship between them, develops the map of structural mesoshifts for electronics industry and systematizes the data on the significant (from the author’s viewpoint) structural changes in this area of the national economy. The main structural shifts in the contemporary electronics industry of Russia include the transition to the strategies of intensive development of domestic manufacturers of electronic components, voluntary multiple increase in the volume of products positioned as goods of domestic production, forced growth of localization of electronic production, mass promotion of software and hardware complexes to the market as a product. Sustainable development of the companies of electronics industry is identified as the potential emerging structural shift.
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18

Hadi Imam Sutaji and Ali Warsito. "Pengenalan Beberapa Komponen Elektronika Dasar dan Aplikasinya di Lingkungan Sekitar Sebagai Upaya Menumbuhkan Minat pada Bidang Elektronika dan Teknologi." ALKHIDMAH: Jurnal Pengabdian dan Kemitraan Masyarakat 2, no. 4 (October 2, 2024): 15–22. https://doi.org/10.59246/alkhidmah.v2i4.1065.

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Electronics and technology are inseparable from students' activities at school as well as their lives as children in the family environment. As part of technology, electronics also continues to developments in many ways in various fields, one of the which is manifested in electronic circuit systems. So that it functions as it should, the use of electronic components is very important on the electronic circuit system. Therefore, theory and introduction to basic electronic components and their applications in the surrounding environment need to be carried out by students. The purpose is to grow a sense of interest as motivation to develop potential, talent and interest in the field of electronics in particular and technology in general so that in the future it is hoped that students will not only become users but are also expected to become inventors, developers and innovators in the field of electronics and technology.
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19

Shpak, V. V. "Development Strategy for the Electronic Industry of the Russian Federation and Its Financial Support." Economics of Science 7, no. 3 (November 5, 2021): 195–204. http://dx.doi.org/10.22394/2410-132x-2021-7-3-195-204.

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The purpose of the article is to substantiate how to solve the problem set by the President of Russia to achieve sovereignty in the development and production of electronics and electronic component base. The Government developed methods for achieving this goal and approved by the Strategy for the Development of the Electronic Industry until 2030. The most powerful and dynamically developing competitor of domestic electronics in China, therefore, it is advisable to consider the development of domestic electronics, having isomorphic processes at individual enterprises and in electronics in China as a scale line. Now a bottleneck in the development of domestic electronics has emerged – this is the lack of proactive and duplicate funding for breakthrough technologies. The article presents an asymmetric version of the response to the total and increasing Western sanctions, the main element of which should be non-monetary investment certificates.
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20

Fleming, Bill. "Advanced Automotive Electronics [Automotive Electronics]." IEEE Vehicular Technology Magazine 8, no. 4 (December 2013): 4–12. http://dx.doi.org/10.1109/mvt.2013.2281677.

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21

Swann, Michael. "Electronics Projects using Electronics Workbench." Electronics Education 1999, no. 1 (1999): 33. http://dx.doi.org/10.1049/ee.1999.0019.

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22

Matveev, V. I. "ELECTRONICS OF RUSSIA – 2022." Kontrol'. Diagnostika, no. 296 (February 2023): 57–64. http://dx.doi.org/10.14489/td.2023.02.pp.057-064.

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The article provides a brief description of the first exhibition of electronic products made only in Russia. The purpose of the exhibition is import substitution and acceleration of the development of own technologies for the production of elements and products of modern electronics. The leading Russian companies, their main specialization and examples of modern electronic and radio-electronic products are presented.
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Matveev, V. I. "ELECTRONICS OF RUSSIA – 2023." Kontrol'. Diagnostika, no. 308 (February 2024): 63–68. http://dx.doi.org/10.14489/td.2024.02.pp.063-068.

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A brief description of the next (second) exhibition of electronic products only of Russian production is given. The purpose of the exhibition is to accelerate the development of our own technologies for the production of elements and products of modern electronics and import substitution. Leading Russian manufacturers, their main specialization and examples of modern electronic and radio-electronic products are presented.
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Rodrigues, Eduardo M. G., Radu Godina, and Edris Pouresmaeil. "Industrial Applications of Power Electronics." Electronics 9, no. 9 (September 19, 2020): 1534. http://dx.doi.org/10.3390/electronics9091534.

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Electronic applications use a wide variety of materials, knowledge, and devices, which pave the road to creative design, development, and the creation of countless electronic circuits with the purpose of incorporating them in electronic products. Therefore, power electronics have been fully introduced in industry, in applications such as power supplies, converters, inverters, battery chargers, temperature control, variable speed motors, by studying the effects and the adaptation of electronic power systems to industrial processes. Recently, the role of power electronics has been gaining special significance regarding energy conservation and environmental control. The reality is that the demand for electrical energy grows in a directly proportional manner with the improvement in quality of life. Consequently, the design, development, and optimization of power electronics and controller devices are essential to face forthcoming challenges. In this Special Issue, 19 selected and peer-reviewed papers discussing a wide range of topics contribute to addressing a wide variety of themes, such as motor drives, AC-DC and DC-DC converters, electromagnetic compatibility and multilevel converters.
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YISA, S. N., and T. M. SABA. "Opportunities and Skills needed for Effective Enterprising in Industrial and Consumer Electronics." Kampala International University Journal of Education Three, One (May 31, 2023): 1–12. http://dx.doi.org/10.59568/kjed-2023-3-1-01.

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The rate of unemployment in Nigeria calls for a drastic and effective approach and solution. The study sought to identify the opportunities and skills needed for effective entrepreneurship in industrial and consumer electronics. Two research questions and two hypotheses were formulated. A descriptive survey research design was adopted for the study. The study's sole instrument was a questionnaire. The population of the study was made up of 100: 28 electrical and electronic lecturers in tertiary institutions in Niger State, 8 electrical and electronic workshop personnel, and 64 electronics technicians in Niger State. All the lecturers and workshop personnel were used while propulsive sampling techniques were used to select the 64 electronics technicians in Niger State. Mean and standard deviation were used to answer the research questions, while ANOVA was used to analyze the hypotheses to determine whether they were significant at the (P .05) level. The findings that emerged, among others, are that there are a lot of entrepreneurship opportunities available in industrial and consumer electronics, and there are a lot of skills needed by industrial and consumer electronics entrepreneurs. There are no significant differences between the mean responses of lecturers, workshop personnel, and electronics technicians on the entrepreneurship opportunities in industrial and consumer electronics in Niger State. The following recommendations were made, among others: There should be more awareness of the entrepreneurial opportunities in industrial and consumer electronics, and there should be training and retraining for those who wish to be involved in electronics entrepreneurship.
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Sekitani, Tsuyoshi. "(Invited, Digital Presentation) Ultra-Thin Organic Integrated Circuits Enabling Bio-Signal Monitoring." ECS Meeting Abstracts MA2022-01, no. 10 (July 7, 2022): 799. http://dx.doi.org/10.1149/ma2022-0110799mtgabs.

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Digital technology has permeated our society, and a wide variety of electronic devices are now in use. In particular, the development of electronic devices for biometric measurements, such as wearable electronics, has been remarkable, and coupled with research and development of high-speed communication and artificial intelligence (AI), many social implementations are being presented. Our group has been conducting research and development on flexible and stretchable electronic systems, which are flexible, soft like rubber, and lightweight, by integrating functional organic nano-materials. In this research activity, our flexible and stretchable electronics have obtained certification for medical devices and are promoting the development of new electronics for use in medical institutions. In this presentation, I would like to introduce our recent activities on the flexible and stretchable electronics utilizing the nanoscience and technology, and developed low-noise and ultra-flexible systems for measuring biological action potentials (electroencephalogram; EEG and electrocardiogram ; ECG).
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V R Nandigana, Vishal. "Fluidic Electronics: Logic Gates." International Journal of Science and Research (IJSR) 10, no. 5 (May 27, 2021): 676–78. https://doi.org/10.21275/sr21516205229.

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28

Abgrall, N., M. Amman, I. J. Arnquist, F. T. Avignone, A. S. Barabash, C. J. Barton, P. J. Barton, et al. "The Majorana Demonstrator readout electronics system." Journal of Instrumentation 17, no. 05 (May 1, 2022): T05003. http://dx.doi.org/10.1088/1748-0221/17/05/t05003.

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Abstract The Majorana Demonstrator comprises two arrays of high-purity germanium detectors constructed to search for neutrinoless double-beta decay in 76Ge and other physics beyond the Standard Model. Its readout electronics were designed to have low electronic noise, and radioactive backgrounds were minimized by using low-mass components and low-radioactivity materials near the detectors. This paper provides a description of all components of the Majorana Demonstrator readout electronics, spanning the front-end electronics and internal cabling, back-end electronics, digitizer, and power supplies, along with the grounding scheme. The spectroscopic performance achieved with these readout electronics is also demonstrated.
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Habboush, Shayma, Sara Rojas, Noel Rodríguez, and Almudena Rivadeneyra. "The Role of Interdigitated Electrodes in Printed and Flexible Electronics." Sensors 24, no. 9 (April 24, 2024): 2717. http://dx.doi.org/10.3390/s24092717.

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Flexible electronics, also referred to as printable electronics, represent an interesting technology for implementing electronic circuits via depositing electronic devices onto flexible substrates, boosting their possible applications. Among all flexible electronics, interdigitated electrodes (IDEs) are currently being used for different sensor applications since they offer significant benefits beyond their functionality as capacitors, like the generation of high output voltage, fewer fabrication steps, convenience of application of sensitive coatings, material imaging capability and a potential of spectroscopy measurements via electrical excitation frequency variation. This review examines the role of IDEs in printed and flexible electronics since they are progressively being incorporated into a myriad of applications, envisaging that the growth pattern will continue in the next generations of flexible circuits to come.
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Yan, Shao Bing, and Wen Qi Zhu. "Research on China's Electronics Listed Company's Financial Risk Probability and Statistics." Advanced Materials Research 430-432 (January 2012): 996–99. http://dx.doi.org/10.4028/www.scientific.net/amr.430-432.996.

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Different from the traditional manufacturing industry, electronics industry is representative of high-tech industry and its financial risk has its own characteristics. In this paper, I choose 2000-2009 electronic financial data of listed companies as samples and use two yuan logistic regression analysis to build an assessment of China's electronics companies in financial risk probability model for the electronic companies to evaluate their own financial risks, provide a simple reference to the views to reduce the financial risk and give the basic risk prediction for the electronics company's mergers and acquisitions objects.
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Sim, Kyoseung, Zhoulyu Rao, Faheem Ershad, and Cunjiang Yu. "Stretchable Electronics: Rubbery Electronics Fully Made of Stretchable Elastomeric Electronic Materials (Adv. Mater. 15/2020)." Advanced Materials 32, no. 15 (April 2020): 2070119. http://dx.doi.org/10.1002/adma.202070119.

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32

Jung, Hyunsuk, Wonbeom Lee, and Jiheong Kang. "Recent Progress in Printing Conductive Materials for Stretchable Electronics." Journal of Flexible and Printed Electronics 1, no. 2 (December 2022): 137–53. http://dx.doi.org/10.56767/jfpe.2022.1.2.137.

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Printed electronics received a great attention in both research and commercialization since it allows fabrication of low-cost, large area electronic devices on various substrates. Printed electronics plays a critical role in facilitating stretchable electronics since it allows patterning newly developed stretchable conductors which is difficult to be achieved with conventional silicon-based microfabrication technologies, such as photolithography and vacuum-based techniques. To realize printed electronics which is necessary for the development of stretchable electronics, printing technologies, formulation of conductive inks, and integration of functional devices have been widely investigated in the recent years. This review summarizes principles and recent development of printing techniques, materials for stretchable conductors and their applications in stretchable electronics using various printing techniques. The challenge is that only a few researches satisfying both excellent materials properties and good printability were reported. Future efforts will greatly expand the possibilities of using printed electronics for stretchable electronics.
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Kurniawati, Renny, Nawiyah Nawiyah, and Bayu Prabowo Sutjiatmo. "Indonesia's Electronic Export Potential in The Global Market with Gravity Panel Model Approach." West Science Journal Economic and Entrepreneurship 1, no. 11 (November 30, 2023): 389–97. http://dx.doi.org/10.58812/wsjee.v1i11.397.

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The purpose of this study is to calculate Indonesia's electronic export potential to 14 countries during the period 2007-2022 using a panel-gravity approach using the PPML technique. The results of this study confirm the positive and significant relationship between Indonesia's electronics exports and the main component of the gravity model, namely Indonesia's GDP and trading partners. Another variability is the economic openness of trading partners has a positive relationship and exchange rates have a positive but not significant relationship. Variability of distance, and trade agreements have a negative relationship with Indonesia's electronic exports. The results for electronic export potential show that Indonesian electronics still have a lot of leverage to increase its exports to 9 countries. Thus, the position of the electronics industry as a potential industry can be carried out by targeting these countries. But to capitalize on the potential benefits of electronics exports, policymakers need to strengthen infrastructure and regulations related to the electronics industry.
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Rodriguez, R. X., K. Church, and X. Chen. "Heterogeneous Process Development for Electronic Device Packaging with Direct Printed Additive Manufacturing." International Symposium on Microelectronics 2012, no. 1 (January 1, 2012): 000961–66. http://dx.doi.org/10.4071/isom-2012-wp56.

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Next generation electronics will not change drastically in function; batteries will last longer, devices will have more functions and devices will take unique shapes, but for the next several years, electronics will travel the path it has been traveling for a couple of decades. To meet the demands of more functions per device and unique shapes, the status quo of electronic manufacturing cannot persist. Solder, wire bonds, FR4, printed circuit boards, surface mount and packaging will fight for survival, but just as hand held phones have evolved, so will the electronics that support them. Standard electronic packaging techniques are reaching size and density limits forcing a search for alternative approaches. The idea of using Additive Manufacturing as an alternative for packaging has not been taken seriously, but there is an opportunity to demonstrate the significant advantages of true 3D electronic packages by allowing the package to be the printed circuit board and by utilizing direct print and bare die approaches to print and structure diverse electronics.
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Zhao, Yuhang, and Jie Jiang. "Recent Progress on Neuromorphic Synapse Electronics: From Emerging Materials, Devices, to Neural Networks." Journal of Nanoscience and Nanotechnology 18, no. 12 (December 1, 2018): 8003–15. http://dx.doi.org/10.1166/jnn.2018.16428.

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To realize intelligent functions in electronic devices like a human brain, it is important to develop the electronic devices that can imitate biological neurons and synapses (synaptic electronics). In this paper, we review the critical learning mechanisms for synaptic plasticity. Different electronic devices were developed to mimic biological synapses, such as atomic switch, phase change memory, ferroelectric memory, and electric-double-layer transistors. More importantly, several groups have realized the artificial neuromorphic network using multi-gate transistor architecture. The leap from synapse to neuron to neural network, thus, has been systematically realized using thin films and nanomaterials. The emerging synaptic electronics can have a broader applications and brighter future in the next-generation intelligent nano-electronics.
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36

Marqués-González, Santiago, and Paul J. Low. "Molecular Electronics: History and Fundamentals." Australian Journal of Chemistry 69, no. 3 (2016): 244. http://dx.doi.org/10.1071/ch15634.

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The increasing difficulties of meeting ‘Moore’s Law’ rates of progress in conventional semiconductor electronics, coupled with the advent of methods capable of measuring the electronic properties of single molecules in a laboratory setting, have seen a surge of activity in the field of molecular electronics over the last decade. However, the concepts of molecular electronics are far from new, and the basic premise and ideas of molecular electronics have been shadowing those of solid-state semiconductor electronics since the middle of the 20th century. In this Primer Review, we introduce the topic of molecular electronics, drawing on some of the earliest expressions of the fundamental concepts, and summarizing key concepts to provide the interested reader with an entry to this fascinating field of science and emerging technology.
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Yu, Jing Zhu, Qiang Liu, Guo Hua Fu, and Chun Yu Mao. "Construction of Analog Electronics Course Design a Study of Quality Control System." Applied Mechanics and Materials 220-223 (November 2012): 3068–71. http://dx.doi.org/10.4028/www.scientific.net/amm.220-223.3068.

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Curriculum design is the key to teaching practice in analog electronics design, the curriculum design of analog electronics technology is a follow-up course who after completing the analog electronics. Through the steps of the design, welding, commissioning, and eventually completed the course requirements of the physical works. The design of analog electronic courses can let students understand the design process of an electronic works which for the tops of design, drawing, welding, assembling, testing, etc. Greatly improve the students’ practical ability. On the other hand, by the application of theoretical knowledge, students can also greatly improve the theory and solve practical problems. The ability to learn lots of knowledge can not be learned from textbooks. But at the same time, in curriculum design, will also facing unexpected contradictions, these contradictions show the contradiction between the analog electronics course design and quality control. Therefore, in order to solve the problems in the design of analog electronics courses, improve the quality of students who have completed their work. The curriculum design of analog electronics technology must have a strong quality control system compatible with the curriculum design.
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Kharchenko, Sergey B. "FLEXIBLE ELECTRONICS TECHNOLOGIES: MATERIALS, PRODUCTION, AND APPLICATIONS." EKONOMIKA I UPRAVLENIE: PROBLEMY, RESHENIYA 9/6, no. 150 (2024): 70–77. http://dx.doi.org/10.36871/ek.up.p.r.2024.09.06.008.

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The article reviews modern flexible electronics technologies, including materials, manufacturing methods, and their main applications. It provides an analysis of key materials, such as flexible substrates and conductive materials, which play an important role in the creation of flexible electronics. Printing and deposition technologies used to produce flexible electronic devices are described. Application areas include consumer electronics, medical devices, industrial and military solutions, as well as the role of flexible electronics in the Internet of Things (IoT). Particular attention is paid to current challenges and prospects for technology development.
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Vágnerová, Lucie. "‘Nimble Fingers’ in Electronic Music: Rethinking sound through neo-colonial labour." Organised Sound 22, no. 2 (July 12, 2017): 250–58. http://dx.doi.org/10.1017/s1355771817000152.

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How can historians of electronic music address the factory labour of the global underclass of women building electronics used in sound technologies? How can we speak to the repetitive work of women who are racially and sexually stereotyped as having ‘nimble fingers’, being ‘detail oriented’ and ‘obedient’? Although women workers in electronics assembly are already de facto entangled in contemporary sound production, scholars have yet to enfold their lives and labour into histories of electronic music. I situate electronic sound technologies since the 1960s in the contexts of the global division of labour and the intimate disciplining of women’s bodies, and investigate the discursive fallout of transnational subcontracting in the electronics industry. I argue that rethinking the category ‘women in electronic music’ is a necessary step for sound studies and musicology, and I call for a new disciplinary understanding of electronic sound and audio as fundamentally neo-colonial.
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Monteblanco, Elmer, Christian Ortiz Pauyac, Williams Savero, J. Carlos RojasSanchez, and A. Schuhl. "ESPINTRÓNICA, LA ELECTRONICA DEL ESPÍN SPINTRONICS, SPIN ELECTRONICS." Revista Cientifica TECNIA 23, no. 1 (March 10, 2017): 5. http://dx.doi.org/10.21754/tecnia.v23i1.62.

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En la actualidad el desarrollo de la tecnología nos ha conducido a elaborar dispositivos nanométricos capaces de almacenar y procesar información. Estos dispositivos serían difíciles de imaginar en la electrónica, la cual se basa en la manipulación de la carga eléctrica del electrón. Sin embargo, gracias a los avances en la física teórica y experimental en el campo de la materia condensada, estos dispositivos ya son una realidad, perteneciendo a lo que actualmente se denomina la electrónica del espín o espintrónica, la cual basa su funcionalidad en el control del espín del electrón, una propiedad que sólo puede ser concebida a nivel cuántico. En el presente artículo revisaremos esta nueva perspectiva, describiendo la Magnetorresistencia Gigante y de Efecto Túnel, la transferencia de momento de espín y sus respectivas aplicaciones como son las memorias MRAM, nano-osciladores y válvulas laterales de espín. Palabras clave.- Espintrónica, Magnetorresistencia, GMR, TMR, MRAM, Nano-osciladores, dinámica de magnetización, Efecto Hall de spin, Transferencia de torque de spin. ABSTRACTCurrent technology seeks to develop nanoscale devices capable of storing and processing information. These devices would be difficult to make in the area of electronics, which is based on the manipulation of electric charge. However, thanks to advances in experimental and theoretical physics in the field of condensed matter, these devices are already a reality, belonging to the field of what we now call spintronics, which bases its functionality on the control of the electron’s spin, a property that can only be conceived at the quantum level. In this article we review this new perspective, describing giant- and tunneling- magnetoresistance, the spin transfer torque, and their applications such as MRAM memories, nano-oscillators and lateral spin valves. Keywords.- Spintronics, Magnetoresistance, GMR, TMR, MRAM, Nano-oscillators, Magnetization dynamics, Spin Hall effect, Spin transfer torque.
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Xing, Wenkui, Yue Xu, Chengyi Song, and Tao Deng. "Recent Advances in Thermal Interface Materials for Thermal Management of High-Power Electronics." Nanomaterials 12, no. 19 (September 27, 2022): 3365. http://dx.doi.org/10.3390/nano12193365.

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With the increased level of integration and miniaturization of modern electronics, high-power density electronics require efficient heat dissipation per unit area. To improve the heat dissipation capability of high-power electronic systems, advanced thermal interface materials (TIMs) with high thermal conductivity and low interfacial thermal resistance are urgently needed in the structural design of advanced electronics. Metal-, carbon- and polymer-based TIMs can reach high thermal conductivity and are promising for heat dissipation in high-power electronics. This review article introduces the heat dissipation models, classification, performances and fabrication methods of advanced TIMs, and provides a summary of the recent research status and developing trends of micro- and nanoscale TIMs used for heat dissipation in high-power electronics.
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42

Leclerc, Mario, and Tricia Breen Carmichael. "Focus on green printed electronics." Flexible and Printed Electronics 10, no. 1 (January 22, 2025): 010201. https://doi.org/10.1088/2058-8585/adab02.

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Abstract This Editorial summarizes the content of the Focus Issue on green printed electronics, featuring contributions from the NSERC green electronics network and others. The collection brought together original research on green synthetic methods for electronic materials, green printing processes, and the design, modelling, and fabrication of green printed devices.
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43

Meidanshahi, Reza Vatan, Shobeir K. S. Mazinani, Vladimiro Mujica, and Pilarisetty Tarakeshwar. "Electronic transport across hydrogen bonds in organic electronics." International Journal of Nanotechnology 12, no. 3/4 (2015): 297. http://dx.doi.org/10.1504/ijnt.2015.067214.

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Mahns, Benjamin, Friedrich Roth, Mandy Grobosch, Susi Lindner, Martin Knupfer, Tobat P. I. Saragi, Thomas Reichert, Josef Salbeck, and Torsten Hahn. "Electronic properties of spiro compounds for organic electronics." Journal of Chemical Physics 136, no. 12 (March 28, 2012): 124702. http://dx.doi.org/10.1063/1.3698280.

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Yun, Yong Ju, Jongil Ju, Joong Hoon Lee, Sung-Hwan Moon, Soon-Jung Park, Young Heon Kim, Won G. Hong, et al. "Highly Elastic Graphene-Based Electronics Toward Electronic Skin." Advanced Functional Materials 27, no. 33 (July 27, 2017): 1701513. http://dx.doi.org/10.1002/adfm.201701513.

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46

Schöttle, Markus. "Electronics." ATZelektronik worldwide 8, no. 5 (September 25, 2013): 3. http://dx.doi.org/10.1365/s38314-013-0190-x.

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47

Hambley, A. R. "Electronics." IEEE Aerospace and Electronic Systems Magazine 15, no. 4 (April 2000): 46–48. http://dx.doi.org/10.1109/maes.2000.839635.

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ITOZAKI, Hideo, Shuichi TAHARA, Takashi NOGUCHI, Hisao HAYAKAWA, Youichi MATSUBARA, and Noriharu TAMADA. "Superconducting Electronics. Talking about Superconducting Electronics." TEION KOGAKU (Journal of Cryogenics and Superconductivity Society of Japan) 31, no. 11 (1996): 606–20. http://dx.doi.org/10.2221/jcsj.31.606.

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Fleming, Bill. "New Automotive Electronics Technologies [Automotive Electronics]." IEEE Vehicular Technology Magazine 7, no. 4 (December 2012): 4–12. http://dx.doi.org/10.1109/mvt.2012.2218144.

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Fleming, Bill. "Advances in Automotive Electronics [Automotive Electronics]." IEEE Vehicular Technology Magazine 9, no. 3 (September 2014): 3–23. http://dx.doi.org/10.1109/mvt.2014.2333615.

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