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KAIST Participates in the World Economic Forum's Annual Meeting of the New Champions 2015 in China
KAIST’s president and its professors actively engage in discussions of major issues on higher education, technology innovation, and industry-university collaboration with global leaders from across all sectors.
President Steve Kang of KAIST participated in the Annual Meeting of the New Champions 2015 (a.k.a., Summer Davos Forum) hosted by the World Economic Forum (WEF). With the theme of “Charting a New Course for Growth,” the Summer Davos Forum took place on September 9-11, 2015 in, Dalian, China.
Currently, KAIST is a member of the Global University Leaders Forum (GULF) of WEF, a gathering of the presidents of the top 25 universities in the world, including Harvard University, Massachusetts Institute of Technology, University of Tokyo, University of Oxford, Peking University, and National University of Singapore. GULF allows university leaders an opportunity to have high-level dialogues on higher education and research and explore prospects for cooperative ventures.
President Kang led the discussion of the GULF session at the Summer Davos Forum, which was held on September 10, 2015, with 25 university leaders as well as two business leaders from Chinese companies: Huawei Technologies Co. Ltd., and Sanofi China. The participants shared candid perspectives on industry-university collaboration, particularly the need for such partnerships in Asia.
In addition, KAIST hosted the fourth IdeasLab session, entitled “Bio versus Nano Materials, on September 9, 2015. At the session, four KAIST professors held an in-depth debate and discussion with the audience on whether the next industrial revolution would be driven by advances in biomaterials or nanomaterials.
The topics under discussion were:
- New materials that mimic biology by Professor Hea Shin Lee
- Bio-based materials that replace petroleum-based materials by Professor Sang Yup Lee
- New materials designed at sub-nano scale by Professor Hee Tae Jung
- A hydrogen economy with nanomaterials by Professor Eun Ae Cho
Since its establishment in 2007, the Summer Davos Forum has become the biggest business and political gathering in Asia, held annually either in Dalian or Tianjin, China. The Forum has attracted more than 1,500 participants primarily from emerging nations such as China, India, Russia, Mexico, and Brazil, and has offered an open platform to address issues important to the region and the global community.
2015.09.14 View 9484 -
KAIST to Hold a Colloquium on the Internet of Things and Open Stack
With the support of the Ministry of Science, ICT, and Future Planning of Korea, KAIST hosted a colloquium on the Internet of Things (IoT) and Open Stack at the KAIST Research Center for Global Cooperation located in Pangyo. The upcoming event was organized to provide an overview of the technological trends to IT companies and foster their success in the global market.
The colloquium invited numerous field-experts as speakers and discussed the influence of IoT and OpenStack on the small- and medium-sized companies in Korea.
Professor Gwan-Hoo Lee from the American University joined as a speaker and shared his insights of how IoT would change the global business environment. He introduced various business models developed by Microsoft, Intel, Apple, Google, and Cisco and discussed how Korean companies could utilize the existing tools and strategy to succeed in the global market. His talk focused specifically on the importance of overseas partnerships and technology stack analysis.
President Hyun-Jung Jang from the Korean OpenStack Community also gave a speech on global partnership through OpenStack. He discussed the future trends of OpenStack and why companies should invest in the field.
KAIST used the event as an opportunity to provide information to domestic companies that are interested in building partnerships with overseas companies and in developing new IoT and OpenStack technology.
More information about the event can be provided online at www.ictc.or.kr.
2015.09.11 View 5884 -
KAIST's Mathematician Reveals the Mechanism for Sustaining Biological Rhythms
Our bodies have a variety of biological clocks that follow rhythms or oscillations with periods ranging from seconds to days. For example, our hearts beat every second, and cells divide periodically. The circadian clock located in the hypothalamus generates twenty-four hour rhythms, timing our sleep and hormone release. How do these biological clocks or circuits generate and sustain the stable rhythms that are essential to life?
Jae Kyoung Kim, who is an assistant professor in the Department of Mathematical Sciences at KAIST, has predicted how these biological circuits generate rhythms and control their robustness, utilizing mathematical modeling based on differential equations and stochastic parameter sampling. Based on his prediction, using synthetic biology, a research team headed by Matthew Bennett of Rice University constructed a novel biological circuit that spans two genetically engineered strains of bacteria, one serves as an activator and the other as a repressor to regulate gene expression across multiple cell types, and found that the circuit generates surprisingly robust rhythms under various conditions.
The results of the research conducted in collaboration with KAIST (Korea Institute of Science and Technology), Rice University, and the University of Houston were published in Science (August 28, 2015 issue). The title of the paper is "Emergent Genetic Oscillations in a Synthetic Microbial Consortium" .
The top-down research approach, which focuses on identifying the components of biological circuits, limits our understanding of the mechanisms in which the circuits generate rhythms. Synthetic biology, a rapidly growing field at the interface of biosciences and engineering, however, uses a bottom-up approach.
Synthetic biologists can create complex circuits out of simpler components, and some of these new genetic circuits are capable of fluctuation to regulate gene production. In the same way that electrical engineers understand how an electrical circuit works as they construct batteries, resistors, and wires, synthetic biologists can understand better about biological circuits if they put them together using genes and proteins. However, due to the complexity of biological systems, both experiments and mathematical modeling need to be applied hand in hand to design these biological circuits and understand their function.
In this research, an interdisciplinary approach proved that a synthetic intercellular singling circuit generates robust rhythms to create a cooperative microbial system. Specifically, Kim's mathematical analysis suggested, and experiments confirmed, that the presence of negative feedback loops in addition to a core transcriptional negative feedback loop can explain the robustness of rhythms in this system. This result provides important clues about the fundamental mechanism of robust rhythm generation in biological systems.
Furthermore, rather than constructing the entire circuit inside a single bacterial strain, the circuit was split among two strains of Escherichia coli bacterium. When the strains were grown together, the bacteria exchanged information, completing the circuit. Thus, this research also shows how, by regulating individual cells within the system, complex biological systems can be controlled, which in turn influences each other (e.g., the gut microbiome in humans).
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Ye Chen, a graduate student in Bennett's laboratory at Rice University, and Jae Kyoung Kim, an assistant professor at KAIST and a former postdoctoral fellow at Ohio State University, are the lead authors of the paper. The co-authors are Rice graduate student Andrew Hirning and Krešimir Josic?, a professor of mathematics at the University of Houston. Bennett is the Assistant Professor of the Biochemistry and Cell Biology Department at Rice University.
About the researcher: While Jae Kyoung Kim is a mathematician, he has also solved various biological puzzles in collaboration with various experimental laboratories of Matthew Bennett at Rice University, David Virshup at Duke and the National University of Singapore, Carla Finkielstein at Virginia Polytechnic Institute and State University, Choo-Gon Lee at the Florida State University, Seung-Hee Yoo at the Medical School of the University of Texas, Toru Takumi at RIKEN Brain Science Institute, and Travis Wager at Pfizer Inc. He has used non-linear dynamics and stochastic analysis to understand the function of biochemical networks in biological systems. In particular, he is interested in mechanisms generating and regulating biological rhythms.
Picture 1: This schematic image is the design of a biological circuit between two strains of bacteria and the part of differential equations used to understand the function of the biological circuit.
Picture 2: The core transcriptional negative feedback loop and additional negative feedback loop in the biological circuit (picture 1) generate robust rhythms. The snapshots correspond the red dots in the time series graph.
2015.08.31 View 9207 -
KAIST Develops Fiber-Like Light-Emitting Diodes for Wearable Displays
Professor Kyung-Cheol Choi and his research team from the School of Electrical Engineering at KAIST have developed fiber-like light-emitting diodes (LEDs), which can be applied in wearable displays. The research findings were published online in the July 14th issue of Advanced Electronic Materials.
Traditional wearable displays were manufactured on a hard substrate, which was later attached to the surface of clothes. This technique had limited applications for wearable displays because they were inflexible and ignored the characteristics of fabric.
To solve this problem, the research team discarded the notion of creating light-emitting diode displays on a plane. Instead, they focused on fibers, a component of fabrics, and developed a fiber-like LED that shared the characteristics of both fabrics and displays.
The essence of this technology, the dip-coating process, is to immerse and extract a three dimensional (3-D) rod (a polyethylene terephthalate fiber) from a solution, which functions like thread. Then, the regular levels of organic materials are formed as layers on the thread.
The dip-coating process allows the layers of organic materials to be easily created on the fibers with a 3-D cylindrical structure, which had been difficult in existing processes such as heat-coating process. By controlling of the withdrawal rate of the fiber, the coating's thickness can also be adjusted to the hundreds of thousandths of a nanometer.
The researchers said that this technology would accelerate the commercialization of fiber-based wearable displays because it offers low-cost mass production using roll-to-roll processing, a technology applied to create electronic devices on a roll of flexible plastics or metal foils.
Professor Choi said, “Our research will become a core technology in developing light emitting diodes on fibers, which are fundamental elements of fabrics. We hope we can lower the barrier of wearable displays entering the market.”
The lead author of the published paper, Seon-Il Kwon, added, “This technology will eventually allow the production of wearable displays to be as easy as making clothes.”
Picture 1: The Next Generation Wearable Display Using Fiber-Based Light-Emitting Diodes
Picture 2: Dip-Coating Process to Create Fiber-Based Light-Emitting Diodes
Picture 3: Fiber-Based Light-Emitting Diodes
2015.08.11 View 13675 -
Professor Sang-Min Bae Receives the 2015 Red Dot Design Award
Professor Sang-Min Bae and his research team from the Industrial Design Department of KAIST have received three awards from the 2015 Red Dot Design Award: the Best of the Best Award and two Design Concept Awards.
Being one of the most prestigious international design awards, the Red Dot Design Award serves to identify good design concept and innovation that will be the precursors of tomorrow’s great product. Its annual award ceremony will take place on September 25, 2015, at the Red Dot Design Museum in Singapore.
This year, the Award received 4,680 entries from 61 countries, and only the top 5.7% of them was able to garner the awards. In addition to two Red Dot Design Concept Awards, Professor Bae’s team won the Best of the Best Award, coming through a four hundred to one competition.
Awarded the Best of the Best Award, Boxchool is a modular classroom built on shipping containers whose aim is to give underprivileged children equal opportunities for learning. Jointly designed with an IT corporation in Korea, SK Telecom, the container is also a smart classroom.
Boxchool received the Best of the Best Award in recognition of its contribution to giving an equal learning opportunity to needy children, as well as its environmental characteristics.
The research team strengthened the mobility of the container and creatively addressed problems associated with using containers as classrooms such as insulation and inadequate space in environments which hamper teaching. The modular classroom can function in any setting since it can generate electricity from installed solar panels. The rainwater utilization system allows autonomous operation of the classroom.
The team earned the Red Dot Design Concept Award for a self-generating interactive tent, which was jointly designed with Kolon Sport, a Korean outdoor products company, as an industry-university cooperation project. The interactive tent differs from conventional tents by adding features that allow users to engage with the environment. For example, the installed organic solar cells allowed users to have prolonged outdoor activities by supplying electricity generated therefrom. Users can also enjoy greater ventilation. This permits the tent to be utilized as a temporary residence in the third world.
Another recipient of the Red Dot Design Concept Award, Snow Energy is a portable self-generating lamp and charger, which contains a thermo-element, generating electricity from temperature difference. Electricity is generated by pouring hot water inside a tank and cold water into a neighboring space. Snow Energy, which is sustainable and eco-friendly, will be especially helpful during outdoor activities when there is no electricity available.
Professor Bae's research team, ID+IM, has endeavored to address inequality and philanthropy through two projects, the Nanum (a Korean word to mean “sharing”) and the Seed Projects. Since 2005, they have received internationally recognized awards more than 40 times.
Picture 1: Recipient of the Best of the Best Award of the 2015 Red Dot Design Award, Boxchool is a modular classroom built on shipping containers
Picture 2: Recipient of the 2015 Red Dot Design Concept Award, the self-generating interactive tent
Picture 3: Recipient of the 2015 Red Dot Design Concept Award, Snow Energy is a portable self-generating lamp and charger which generates electricity from the temperature difference
2015.08.05 View 11986 -
'Mirror or Mirror' Exhibition at Dongdaemun Design Plaza
An exhibition, called “Mirror or Mirror,” displaying the integration of fashion design and technology took place at Dongdaemun Design Plaza (DDP) in Seoul from July 18-25, 2015. DDP is the center of Korea’s fashion hub.
The exhibition was created by Professor Daniel Pieter Saakes of the Industrial Design Department at KAIST and introduced a new design system reinforced with an interactive technology that incorporates augmented reality into the design process.
Users stand before the Mirror or Mirror system, and by using augmented reality, they can design their own fashion items including clothes based on their need and fashion preferences.
The augmented reality allows users to draw their favorite patterns or new designs over their body, thereby enabling them to check the result immediately and try out a variety of different designs right away.
Professor Saakes said, “Fashion has always been a way to express individual and personal style. With our system, people can easily fulfill such desires, customizing their own designs.”
At the exhibition, visitors also had opportunities to produce their own shirts while using the Mirror or Mirror system.
Picture 1: A user wears a newly designed virtual shirt over her body using augmented reality provided by the Mirror or Mirror system.
Picture 2: The shirt was designed and produced through the Mirror or Mirror system.
2015.07.31 View 11073 -
Affordable Genetic Diagnostic Technique for Target DNA Analysis Developed
Professor Hyun-Gyu Park of the Department of Chemical and Biomolecular Engineering at KAIST has developed a technique to analyze various target DNAs using an aptamer, a DNA fragment that can recognize and bind to a specific protein or enzyme. This technique will allow the development of affordable genetic diagnoses for new bacteria or virus, such as Middle Ease Respiratory Syndrome (MERS). The research findings were published in the June issue of Chemical Communications, issued by the Royal Society of Chemistry in the United Kingdom. The paper was selected as a lead article of the journal.
The existing genetic diagnosis technique, based on molecular beacon probes, requires a new beacon probe whenever a target DNA mutates. As a result, it was costly to analyze various target DNA fragments. To address this problem, Professor Park’s team designed an aptamer that binds and deactivates DNA polymerase. The technique was used in reverse, so that the aptemer did not bind to the polymerase, maintaining its activated state, only if the target DNA was present. These probes are called TagMan probes.
The controlled activation and deactivation of DNA polymerase enables nucleic acid to elongate or dwindle, making it possible to measure fluorescence signals coming from TaqMan probes. This same probe can be used to detect various target DNAs, leading to the development of a new and sensitive genetic diagnostic technique.
Unlike the existing molecular beacon probe technique which requires a new probe for every target DNA, this new technique uses the same fluorescent TaqMan probe, which is cheaper and easier to detect a number of different target nucleic acid fragments. The application of this technique will make the process of identifying and detecting foreign DNAs from pathogens such as virus and bacteria more affordable and simple.
Professor Park said, “This technique will enable us to develop simpler diagnostic kits for new pathogens, such as MERS, allowing a faster response to various diseases. Our technology can also be applied widely in the field of genetic diagnostics.”
Picture: A schematic image of target nucleic acid extracted through the activation and deactivation of DNA polymerase
2015.07.31 View 10875 -
International Undergraduate Conference ICISTS-KAIST 2015 and ICISTS-KAIST Public Colloquium Held on August 3, 2015 at KAIST
The ICISTS-KAIST 2015, an international conference organized by a student organization called the International Conference for the Integration of Science, Technology, and Society at KAIST, was held from August 3rd to 7th at the KAIST campus and ICC Hotel in Daejeon. This year’s conference theme was “Shaping the Future.” Over 300 undergraduate students from more than 20 countries joined the event. The conference offered opportunities to explore emerging issues in science and technology, particularly in the fields of robotics, medicine, and science communication.
Vitalic Buterin, a rising scientist who received the 2014 World Technology Award for his development of the Ethereum Project, and Alan Irwin, a renowned scholar in science communication at the Copenhagen Business School in Denmark, were invited as keynote speakers. The list of other speakers included Stefan Lorenz Sorgner, the Director and Co-founder of the Beyond Humanism Network; Wendell Wallach, a scholar at Yale University's Interdisciplinary Center for Bioethics; and Hideto Nakajima, a professor at the Department of History, Philosophy and Social Studies of Science and Technology at Tokyo Institute of Technology.
As part of the ICISTS-KAIST 2015, ICISTS also hosted a public colloquium on August 5, 2015 at the Science Hall in Daejeon National Science Museum. Ko San, the Director of TIDE Institute; Hyo-Joon Woo, the Chief Executive Officer of Fransen; and Dong-Il Jung, the Chief Executive Officer of iDrone participated as the speakers.
2015.07.29 View 8508 -
Professor Suk-Joong Kang Receives the Richard Brook and Helmholtz Awards
Professor Suk-Joong Kang of KAIST’s Department of Materials Sciences and Engineering received the Richard Brook Award from the European Ceramic Society at its 14th conference held on June 21, 2015, in Toledo, Spain. The award is presented to the most distinguished academic or engineer in ceramics from a non-European country. Professor Kang gave the commemorative lecture after the award ceremony.
Professor Kang is an expert in the field of sintering and microstructural evolution in ceramics and metals. He suggested a new model for grain growth and identified the principles of microstructural evolution.
He also received the 2015 Helmholtz Fellow Award in June. The Helmholtz Association, the largest scientific organization in Germany, confers the award on outstanding senior scientists based outside Germany who have made great academic and research achievements in their fields.
Professor Kang said of the Brook Award, “It is such an honor to receive an award from an eminent global institution. I take this opportunity to thank my students and colleagues for their support, and I will work harder for my research.”
2015.07.20 View 7275 -
Dong-Young Lee, a Doctoral Candidate, Receives the Best Paper Award
Dong-Young Lee, a Ph.D. candidate in the Mechanical Engineering Department, KAIST, received the Best Paper Award at the 18th International Conference on Composite Structures (ICCS). The event was held in Lisbon, Portugal, on June 15-18, 2015. Mr. Lee’s adviser is Professor Dai-Gil Lee of the same department.
The ICCS is held every other year, and is one of the largest and long-established conferences on composite materials and structures in the world. At this year’s conference, a total of 680 papers were presented, among which, two papers were chosen for the Best Paper Award, including Mr. Lee’s.
The paper, entitled “Gasket-integrated Carbon and Silicon Elastomer Composite Bipolar Plate for High-temperature PEMFC,” will be published in the September issue of Composite Structures which is one of the top journals in mechanical engineering as judged by the Google Scholar Metrics rankings.
Mr. Lee dropped the conventional method of PEMFC (Proton Exchange Membrane Fuel Cells) assembly and instead developed a gasket-integrated carbon and silicone elastomer composite bipolar plate. This technology significantly increased the energy efficiency of fuel cells and their productivity.
Mr. Lee said, “I would like to thank the many people who supported me, especially my Ph.D. adviser, Professor Dai-Gil Lee. Without their encouragement, I would have not won this award. I hope my research will contribute to solving energy problems in the future.”
In addition, Professor Joon-Woo Im from Chonbuk National University, Senior Researcher Il-Bum Choi from the Agency for Defense Development, and a fellow doctoral candidate Soo-Hyun Nam from KAIST participated in this research project.
2015.07.09 View 10887 -
Omnidirectional Free Space Wireless Charging Developed
The simultaneous charging of multiple mobile devices at 0.5 meter away from the power source is now possible under the international electromagnetic field guidelines.
Mobile devices, such as smartphones and laptops, have become indispensable portable items in modern life, but one big challenge remains to fully enjoying these devices: keeping their batteries charged.
A group of researchers at KAIST has developed a wireless-power transfer (WPT) technology that allows mobile devices to be charged at any location and in any direction, even if the devices are away from the power source, just as Wi-Fi works for Internet connections. With this technology, so long as mobile users stay in a designated area where the charging is available, e.g., the Wi-Power zone, the device, without being tethered to a charger, will pick up power automatically, as needed.
The research team led by Professor Chun T. Rim of the Nuclear and Quantum Engineering Department at KAIST has made great strides in WPT development. Their WPT system is capable of charging multiple mobile devices concurrently and with unprecedented freedom in any direction, even while holding the devices in midair or a half meter away from the power source, which is a transmitter. The research result was published in the June 2015 on-line issue of IEEE Transactions on Power Electronics, which is entitled “Six Degrees of Freedom Mobile Inductive Power Transfer by Crossed Dipole Tx (Transmitter) and Rx (Receiver) Coils.”
Professor Rim’s team has successfully showcased the technology on July 7, 2015 at a lab on KAIST’s campus. They used high-frequency magnetic materials in a dipole coil structure to build a thin, flat transmitter (Tx) system shaped in a rectangle with a size of 1m2. Either 30 smartphones with a power capacity of one watt each or 5 laptops with 2.4 watts each can be simultaneously and wirelessly charged at a 50 cm distance from the transmitter with six degrees of freedom, regardless of the devices’ three-axes positions and directions. This means that the device can receive power all around the transmitter in three-dimensional space. The maximum power transfer efficiency for the laptops was 34%. The researchers said that to fabricate plane Tx and Rx coils with the six-degree-of-freedom characteristic was a bottleneck of WPT for mobile applications.
Dipole Coil Resonance System (DCRS)
The research team used the Dipole Coil Resonance System (DCRS) to induce magnetic fields, which was developed by the team in 2014 for inductive power transfer over an extended distance. The DCRS is composed of two (transmitting and receiving) magnetic dipole coils, placed in parallel, with each coil having a ferrite core and connected with a resonant capacitor. Comparing to a conventional loop coil, the dipole coil is very compact and has a less dimension. Therefore, a crossed dipole structure has 2-dimension rather than 3-dimension of a crossed loop coil structure. The DCRS has a great advantage to transfer power even when the resonance frequency changes in the range of 1% (Q factor is below 100). The ferrite cores are optimally designed to reduce the core volume by half, and their ability to transfer power is nearly unaffected by human bodies or surrounding metal objects, making DCRS ideal to transmit wireless power in emergency situations. In a test conducted in 2014, Professor Rim succeeded in transferring 209 watts of power wirelessly to the distance of five meters. (See KAIST’s press release on DCRS for details: http://www.eurekalert.org/pub_releases/2014-04/tkai-wpt041714.php.)
Greater Flexibility and Safer Charging
The research team rearranged the two dipole coils from a parallel position to cross them in order to generate rotating magnetic fields, which was embedded in the Tx’s flat platform. This has made it possible for mobile devices to receive power from any direction.
Although wireless-power technology has been applied to smartphones, it could not offer any substantial advantages over traditional wired charging because the devices still require close contact with the transmitter, a charging pad. To use the devices freely and safely, including in public spaces, the WPT technology should provide mobile users with six degrees of freedom at a distance. Until now, all wireless-charging technologies have had difficulties with the problem of short charging distance, mostly less than 10 cm, as well as charging conditions that the devices should be placed in a fixed position. For example, the Galaxy S6 could only be charged wirelessly in a fixed position, having one degree of freedom. The degree of freedom represents mobile devices’ freedom of movement in three-dimensional space.
In addition, the DCRS works at a low magnetic field environment. Based on the magnetic flux shielding technology developed by the research team, the level of magnetic flux is below the safety level of the International Commission on Non-Ionizing Radiation Protection (ICNIRP) guideline (27µT) for general public exposure to electromagnetic field (EMF).
Professor Rim said, “Our transmitter system is safe for humans and compatible with other electronic devices. We have solved three major issues of short charging distance, the dependence on charging directions, and plane coil structures of both Tx and Rx, which have blocked the commercialization of WPT.”
Currently, the research team and KAIST’s spin-off company, TESLAS, Inc., have been conducting pilot projects to apply DCRS in various places such as cafes and offices.
YouTube Link: https://www.youtube.com/watch?v=JU64pMyJioc
Demonstration of 30 Watts Range Omnidirectional Wireless-charging at a Laboratory on KAIST’s Campus
Figure 1: Wide-range omnidirectional wireless-charging system based on DCRS can charge multiple numbers of mobile devices simultaneously in a 1m3 range. The above is a transmitter, and the below is a Samsung Galaxy Note with a receiver embedded inside.
Figure 2: Demonstration of the omnidirectional wireless-charging system (clockwise from top of the left, robust charging despite the presence of metal obstacles, omnidirectional charging, long distance charging, and multiple devices charging)
2015.07.08 View 17420 -
KAIST Professor Sung-Ju Lee Appointed a Technical Program Chair of INFOCOM
Professor Sung-Ju Lee of the Department of Computer Science at KAIST has been appointed to serve as a technical program chair of IEEE INFOCOME. The computer communication conference, started in 1982, is influential in the research fields of the Internet, wireless, and data centers.
Professor Lee is the first Korean to serve as a program chair. He has been acknowledged for his work in network communications. In the 34th conference, which will be held next year, he will take part in selecting 650 experts in the field to become members and supervise the evaluation of around 1,600 papers.
Professor Lee is the leading researcher in the field of wireless mobile network systems. He is a fellow of the Institute of Electrical and Electronics Engineers (IEEE) and served as the general chair of the 20th Association for Computing Machinery (ACM) SIGMOBILE Annual International Conference on Mobile Computing & Networking (MobiCom 2014). He is on the editorial boards of IEEE Transactions on Mobile Computing (TMC) and IEEE Internet of Things Journals.
Professor Lee said, “I hope to continue the traditions of the conference, as well as integrating research from various areas of network communication. I will strive to create a program with high technology transfer probability.”
The 34th IEEE INFOCOM will take place in San Francisco in April 2016.
2015.07.02 View 9621