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DTSTART;TZID=America/New_York:20200219T110000
DTEND;TZID=America/New_York:20200219T120000
DTSTAMP:20260506T002952
CREATED:20200213T195211Z
LAST-MODIFIED:20200213T195211Z
UID:4104-1582110000-1582113600@ece.northeastern.edu
SUMMARY:Electrical and Computer Engineering Seminar: Arjuna Madanayak
DESCRIPTION:Location: ISEC 138 \nMultidimensional Signal Processing Circuits for Low-SWaP Multi-Beam Arrays \nAbstract: \nIn this talk\, array processing circuits that exploit the computing paradigm of approximate computing are explored. Low-size\, -weight\, and -power consumption (SWaP) algorithms and circuits are proposed to achieve thousands of fully-digital beams for emerging applications. The proposed low-SWaP multibeam digital beamformers use approximate computing to enable up to 90% smaller circuit complexity compared to FFT-based techniques used to achieve multiple orthogonal RF beams. Furthermore\, the proposed array processing systems exploit wave physics to improve the performance of key signal processing components in wireless base stations. Specifically\, the spatiotemporal causality properties of electromagnetic plane waves – as described in Special Theory of Relativity – are used in novel multi-port transceiver circuits to improve energy efficiency\, reduce additive white Gaussian noise\, and improve linearity of array receivers at the physical layer. The multi-dimensional frequency-domain region of support (ROS) of all propagating plane waves\, which correspond to wireless propagation channels\, are shown to be confined inside the “Light Cone”. The region of spacetime outside this light cone is a void (elsewhere) within which wireless communications signals cannot propagate. A “cone of silence” appears in the multidimensional spacetime frequency domain\, which demarcates a conical region outside of which waves do not exist. The aim is to spatio-temporally shape noise and transceiver distortion into this electromagnetically silent region so that their presence does not affect the performance of arrays. The technique enables multi-port versions of LNAs\, ADCs\, and DACs for array processing that exploits noise and shaping in multiple dimensions in space and time to greatly improve performance. \nBio: \nDr. Arjuna Madanayake is an Associate Professor of Electrical and Computer Engineering at Florida International University. His research interests include multidimensional signal processing\, array processing\, FPGA and digital systems\, microwave circuits\, VLSI\, analog and mixed-signal circuit design\, fast algorithms\, digital signal processing\, alternative computing\, wireless communications\, mm-wave systems and 5G/6G topics\, sub-THz and THz systems\, satellite communications\, wireless sensing and imaging\, radar sensing\, computing architecture\, internet of things (IoT)\, RF sensing for unmanned aerial systems\, and electronic warfare. He started an Assistant Professorship at the University of Akron in Ohio in 2010\, and received early tenure and promotion to Associate Professor in 2015. Dr. Madanayake was selected as the most outstanding candidate in Electrical Engineering and Computing Sciences category for the NSERC 2009 Canada Post-doctoral Fellowship competition. Dr. Madanayake completed a postdoctoral associateship in 2009 in which he explored multidimensional signal processing and FPGA circuits for beamformer aperture arrays as part of the Canadian Square Kilometer Array (SKA) effort. He completed the Ph.D. and M.Sc. both in Electrical Engineering at the University of Calgary\, specializing in multidimensional signal processing\, circuits and systems\, especially FPGA systems. In his current tenured appointment at FIU\, Dr. Madanayake directs the RF\, Analog and Digital (RAND) Circuits Lab at FIU which has been conducting multiple projects funded by 3 DARPA\, 3 ONR and 7 NSF awards. Arjuna tries to pursue elephant conservation and rural development in Sri Lanka\, and high-end audio engineering as hobbies.
URL:https://ece.northeastern.edu/event/electrical-and-computer-engineering-seminar-arjuna-madanayak/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200218T113000
DTEND;TZID=America/New_York:20200218T123000
DTSTAMP:20260506T002952
CREATED:20200208T022238Z
LAST-MODIFIED:20200208T022238Z
UID:4091-1582025400-1582029000@ece.northeastern.edu
SUMMARY:Electrical and Computer Engineering Seminar: Murat Kocaoglu
DESCRIPTION:Location: ISEC 138 \nCausality: From Learning to Generative Models \nAbstract: \nCausal inference is fundamental for multiple disciplines ranging from medical research to engineering\, statistics\, and economics. It is also central in machine learning and is now becoming a core component of artificial intelligence research. Although causal inference has been studied for a long time in various fields under different frameworks\, today we need tools that can process a large number of variables to handle modern large datasets. The graphical approach to probabilistic causation advocated by Judea Pearl and others provides a way to compactly represent the causal relations using directed acyclic graphs and paves the way for the design of algorithms that can answer causal questions for many variables. \nIn this talk\, Kocaoglu first provides a friendly introduction to causality and explain why causal understanding is important. As his first contribution\, he will propose a framework called entropic causal inference for inferring the causal direction between two variables from data. He will show that entropy can be used to capture the complexity of a causal mechanism. Further\, if the true direction has a simple mechanism\, we can identify it from data. The entropic causal inference framework leverages tools from information theory for causal inference. As his second contribution\, he will show how we can apply causality in deep generative models – deep neural networks used for modeling complex data. He will demonstrate how to define and train a causal deep generative model\, called CausalGAN for generating images with labels. As an extension of generative adversarial networks (GANs)\, CausalGAN allows sampling not only from the observed data distribution but also from the interventional distributions of images. He will conclude with future directions for causal inference and its applications in supervised learning and reinforcement learning. \n \nBio: \nMurat Kocaoglu received his B.S. degree in Electrical – Electronics Engineering with a minor degree in Physics from the Middle East Technical University in 2010. He received his M.S. degree from the Koc University\, Turkey in 2012 under the supervision of Prof. Ozgur B. Akan\, and PhD degree from The University of Texas at Austin in 2018\, under the supervision of Prof. Alex Dimakis and Prof. Sriram Vishwanath. He is currently a Research Staff Member in the MIT-IBM Watson AI Lab in IBM Research\, Cambridge\, Massachusetts. His current research interests include causal inference\, generative adversarial networks\, and information theory
URL:https://ece.northeastern.edu/event/electrical-and-computer-engineering-seminar-murat-kocaoglu/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200218T103000
DTEND;TZID=America/New_York:20200218T113000
DTSTAMP:20260506T002952
CREATED:20200203T211723Z
LAST-MODIFIED:20200215T035349Z
UID:4072-1582021800-1582025400@ece.northeastern.edu
SUMMARY:Engineers Week: Harnessing Metamaterials to Manipulate Electromagnetic and Acoustic Waves
DESCRIPTION:Dr. Xin Zhang\, Professor\, Boston University \nLocation: 138 ISEC \nMetamaterials have been intensively studied and applied to a broad range of practical applications ranging from wireless communications to magnetic resonance imaging. Photonic metamaterials consisting of subwavelength “meta-atoms” have received enormous interest due to their extraordinary and unprecedented optical properties. Specifically\, the effective permittivity and permeability can be tailored and reconfigured to construct metamaterial devices by modulating or actuating the constituent meta-atoms. By leveraging microelectromechanical system (MEMS) technology\, we have developed functional metamaterial devices to manipulate and detect the terahertz waves. In addition\, metamaterials exhibit extraordinary near-field properties to control electric and magnetic field distribution. I will introduce our progress on intelligent magnetic metamaterials to enhance the signal to noise ratio of magnetic resonance imaging. Besides electromagnetic metamaterials\, acoustic metamaterials for sound wave shaping and silencing will also be discussed. \nXin Zhang received her Ph.D. in Mechanical Engineering from the Hong Kong University of Science and Technology (HKUST). She was a Postdoctoral Researcher and then a Research Scientist with the Massachusetts Institute of Technology (MIT). She then joined Boston University (BU) as a Faculty Member\, where she is currently a Professor of Mechanical Engineering\, Electrical & Computer Engineering\, Biomedical Engineering\, Materials Science & Engineering\, and the Photonics Center. Dr. Zhang is the Associate Director of the Boston University Nanotechnology Innovation Center and Director of both the NSF Research Experiences for Undergraduates (REU) and Teachers (RET) Sites in Integrated Nanomanufacturing at Boston University. \nDr. Zhang’s research interests are in the broad areas of microelectromechanical systems (MEMS or microsystems) and metamaterials (acoustic\, electromagnetic\, nonlinear\, photonic\, terahertz\, tunable\, etc.). She has published 160+ papers in interdisciplinary journals\, become both US and EU-US National Academy of Engineering Invitee (ages: 30-45)\, and is an Elected Fellow of AAAS\, AIMBE\, APS\, ASME\, IEEE\, NAI\, and OSA\, and Associate Fellow of AIAA. \nHosted by the Electrical and Computer Engineering Department
URL:https://ece.northeastern.edu/event/engineers-week-harnessing-metamaterials-to-manipulate-electromagnetic-and-acoustic-waves/
LOCATION:138 ISEC\, 360 Huntington Ave\, 138 ISEC\, Boston\, MA\, 02115\, United States
GEO:42.3401758;-71.0892797
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END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200213T150000
DTEND;TZID=America/New_York:20200213T160000
DTSTAMP:20260506T002952
CREATED:20200208T014815Z
LAST-MODIFIED:20200208T014849Z
UID:4088-1581606000-1581609600@ece.northeastern.edu
SUMMARY:Electrical and Computer Engineering Seminar: Najme Ebrahimi
DESCRIPTION:Location: ISEC 136 \nNext Generation of Smart Wireless World: from High Data-Rate Mm-wave Directional Arrays to Reliable and Secured IoT Connectivity for 5G and Beyond \nAbstract: \nThe next generation of smart wireless world requires massive and reliable connectivity as well as high datarate communication and sensing. Consequently\, the immediate response of the wireless world is acquiring the mm-wave (MMW) wireless band (30 GHz–300 GHz) and the development of 5G and beyond. The major challenge of deploying high data-rate communication system at MMW frequency bands is the channel fading and multi-path diffraction effect. Hence\, multiple-element transceivers such as scalable “directional” phased array or massive MIMO are required. Moreover\, the next generation of wireless world is expected to have over one trillion Internet of Things (IoT) devices connected\, requiring secured connectivity such as protection against interference\, jammers\, and eavesdroppers  In this talk\, I will present novel techniques to overcome the challenges for future scalable high data-rate MMW transceiver array from silicon circuit toward RFIC system and packaging. This includes parasitic-insensitive\, power-efficient\, and wideband 2×2 arrays of injection-locked oscillators for efficient local oscillator (LO) distribution and phase shifting (circuit technique)\,  image selection Weaver architecture to significantly reduce the required bandwidth of the LO generation circuitry for the MMW system from conventional 20% to only 4% (RFIC architecture)\, and compact differential aperture coupled LO distribution feed network for compact and scalable antenna-IC integration (packaging). I will also discuss several future directions toward high-frequency signal generation and modulation based on integrating the circuit and electromagnetics fundamental theories for communication and sensing above 100 GHz\, namely\, as 6G.   On the other hand\, employing a “directional” antenna for interference/eavesdropper cancellation for IoTs suffers from side-lobe leakage and requires accurate beam alignment and localization. In this talk\, I will present a novel embedded architecture for a distributed IoT network that utilizes a masterslave full-duplex communication using an omnidirectional antenna to exchange a random modulated phase shift as the secret key while canceling out the eavesdropper effect. I will also discuss two future directions for interference cancellation from circuit level to system level; from cooperative and distributed pulse coupled synchronization for dynamically interference canceling towards wideband interference canceller/filter at RF front-end of IoT devices using a single antenna to turn the radio with one-bit ADC into reality \nBio: \nNajme Ebrahimi is a Post-Doctoral Research Fellow at the University of Michigan (U-M) since September 2017. At the University of Michigan\, she is mainly conducting research on both mm-Wave/THz high data rate communication and sensing in addition to the connectivity of the next generation of distributed Internet-of-Things network. She earned her PhD from the University of California\, San Diego (UCSD) in June 2017\, with a thesis emphasize on enabling high data rate and scalable mm-wave phased array for the next generation of smart wireless world. She received her MS degree and BS degree\, with highest honors\, from Amirkabir University of Technology\, Tehran\, Iran\, in 2011 and Shahid Beheshti University\, Tehran\, Iran\, in 2009\, respectively. She is a member of IEEE Solid-State Circuits and IEEE Microwave Theory and Techniques societies. She is the recipient of PhD Endowed Graduate Fellowship from UCSD (2012-2013) and U-M Departmental Postdoctoral Fellowship (20172019). She is currently serving as the vice-chair of IEEE Southeastern Michigan for Microwave Theory and Techniques Chapter where she is awarded MTT-s Travel Grant (2019). She is selected as 2019 EECS Rising Star by MIT launched Rising-star program and 2020 ISSCC Rising Star by IEEE Solid-State Circuits Society
URL:https://ece.northeastern.edu/event/electrical-and-computer-engineering-seminar-najme-ebrahimi/
LOCATION:136 ISEC\, 360 Huntington Ave\, 136 ISEC\, Boston\, MA\, 02115\, United States
GEO:42.3401758;-71.0892797
X-APPLE-STRUCTURED-LOCATION;VALUE=URI;X-ADDRESS=136 ISEC 360 Huntington Ave 136 ISEC Boston MA 02115 United States;X-APPLE-RADIUS=500;X-TITLE=360 Huntington Ave\, 136 ISEC:geo:-71.0892797,42.3401758
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200212T110000
DTEND;TZID=America/New_York:20200212T120000
DTSTAMP:20260506T002952
CREATED:20200203T195100Z
LAST-MODIFIED:20200203T195100Z
UID:4066-1581505200-1581508800@ece.northeastern.edu
SUMMARY:Electrical and Computer Engineering Seminar: Basak Guler
DESCRIPTION:ISEC 138 \nCoded Computing for Next-Generation Information Processing Systems \nAbstract: \nModern networks are designed to facilitate information processing in large-scale\, highly distributed environments that connect humans with smart machines. Information collected in such networks is often privacy-sensitive\, such as healthcare records\, financial transactions\, or geolocation data. Moreover\, these networks often need to operate in unknown environments using unreliable information sources\, which can lead to various interpretations of the received information. This brings three main challenges in designing effective distributed information-processing frameworks: scalability\, privacy\, and context-awareness. In this talk\, I will discuss how to address these challenges through information and coding theory principles. I will first introduce a fast and privacy-preserving framework for distributed machine learning\, which can provide an order of magnitude speedup over the existing cryptographic approaches. Next\, I will address a major bottleneck for the scalability of large-scale distributed computing frameworks\, the interprocessor communication load\, in the context of distributed graph processing.  To do so\, I will introduce a topology-aware graph allocation and communication strategy using coding theory and demonstrate that it can reduce the inter-processor communication load significantly for both real-world and random graph structures. Finally\, I will discuss the fundamental performance limits of information transmission in context-aware multiuser communication networks. I will characterize the information-theoretic performance limits for lossy transmission of correlated sources in a multi-user communication channel when the communicating parties have access to context information correlated with the sources. \nBio: \nBasak Guler is a postdoctoral scholar at the University of Southern California. She received her M.Sc. and PhD from the Department of Electrical Engineering at the Pennsylvania State University. Her research interests include information and coding theory\, distributed computing\, wireless communications\, graph signal processing\, machine learning\, privacy and security\, and game theory. She is a recipient of the Dr. Nirmal K. Bose Dissertation Award by the Pennsylvania State University\, the Young Scholar Award by the Turkish-American Scientists and Scholars Association\, and was named a Rising Star in EECS by MIT.
URL:https://ece.northeastern.edu/event/electrical-and-computer-engineering-seminar-basak-guler/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200211T113000
DTEND;TZID=America/New_York:20200211T123000
DTSTAMP:20260506T002952
CREATED:20200131T194339Z
LAST-MODIFIED:20200131T194339Z
UID:4058-1581420600-1581424200@ece.northeastern.edu
SUMMARY:Electrical and Computer Engineering Seminar: Qing Qu
DESCRIPTION:Location: ISEC 138 \nTitle: Learning Low-complexity Models from the Data – Geometry\, Optimization\, and Applications \nAbstract: \nToday we are collecting a massive amount of data in forms of images and videos\, that we want to learn from the data themselves to extract useful information and to make predictions. The data are high-dimensional\, but often possess certain low-dimensional structures (e.g.\, sparsity). However\, learning these low-complexity models often results in highly nonconvex optimization problems\, where in the past our understandings of solving them were very limited. In the worst case\, optimizing a nonconvex problem is NP-hard. \nIn this talk\, we present global nonconvex optimization theory and guaranteed algorithms for efficient learning of low-complexity models from high-dimensional data. For several important problems in imaging science (i.e.\, sparse blind deconvolution) and representation learning (i.e.\, convolutional/overcomplete dictionary learning)\, we show that the underlying symmetry and low-complexity structures avoid the worst-case scenarios\, leading to benign global geometric properties of the nonconvex optimization landscapes. In particular\, for sparse blind deconvolution that aims to jointly learn the underlying physical model and sparse signals from convolutions\, the geometric intuitions lead to efficient nonconvex algorithms\, with linear convergence to target solutions. Moreover\, we extended our geometric analysis to convolutional dictionary learning based on its similarity with overcomplete dictionary learning\, providing the first global algorithmic guarantees for both problems. Finally\, we demonstrate our methods on several important applications in scientific discovery and draw connections to learning deep neural networks. \nThis talk is mainly based on one paper appeared in NeurIPS’19 (spotlight)\, and two papers accepted by ICLR’20 (one oral). \nBio:  \nQing Qu is a Moore-Sloan data science fellow at the Center for Data Science\, New York University. He received his Ph.D. from Columbia University in Electrical Engineering in Oct. 2018. He received his B.Eng. from Tsinghua University in Jul. 2011\, and an M.Sc.from the Johns Hopkins University in Dec. 2012\, both in Electrical and Computer Engineering. He interned at U.S. Army Research Laboratory in 2012 and Microsoft Research in 2016\, respectively. His research interest lies at the intersection of the foundation of data science\, machine learning\, numerical optimization\, and signal/image processing. His research focuses on developing computational methods for learning low-complexity models/structures from high dimensional data\, leveraging tools from machine learning\, numerical optimization\, and high dimensional probability/geometry. He is also interested in applying these data-driven methods to various engineering problems in imaging sciences\, scientific discovery\, and healthcare. He is the recipient of Best Student Paper Award at SPARS’15 (with Ju Sun and John Wright)\, and the recipient of Microsoft Ph.D. Fellowship 2016-2018 in machine learning.
URL:https://ece.northeastern.edu/event/electrical-and-computer-engineering-seminar-qing-qu/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200210T110000
DTEND;TZID=America/New_York:20200210T120000
DTSTAMP:20260506T002952
CREATED:20200203T230328Z
LAST-MODIFIED:20200203T230328Z
UID:4070-1581332400-1581336000@ece.northeastern.edu
SUMMARY:Electrical and Computer Engineering Seminar: Xiaolin Xu
DESCRIPTION:Location: ISEC 138 \nEnsuring Hardware Cybersecurity from a Cross-Layer Perspective \nAbstract: \nThe rapid development of the semiconductor industry has significantly increased the number\, complexity\, and applicability of commercial electronics over the past few decades. As a result\, the security and assurance of hardware are playing a critical role in the cyberscape of modern society\, such as national defense\, healthcare\, transportation\, and finances. Hardware has been assumed to be trustworthy and reliable “by default.” However\, this assumption is no longer true\, with an increasing number of attacks reported on the hardware. In practice\, the globalization of semiconductor business poses grave risks from untrusted fabrication and distribution\, where Trojans insertion\, IP cloning\, and counterfeits may happen.    In this talk\, I will present our research efforts dedicated to the hardware-oriented cybersecurity from a cross-layer perspective. Specifically\, I will introduce two frameworks that we built to address these problems in the supply chain and embedded system layers. I will first present an identification technique based on the physical disorder of integrated circuitry that enables the authentication of electronic devices. Then\, I will present a hardware IP protection framework based on logic locking and circuit editing\, which can effectively mitigate the vulnerabilities from untrusted off-shore foundries and supply chains. At the end of the talk\, I will briefly present our scientific achievements in advancing the hardware security in the system and architecture layers\, as well as proposing a future research agenda of this emerging area. \nBio: \nDr. Xiaolin Xu is currently an Assistant Professor in the Department of Electrical and Computer Engineering at the University of Illinois at Chicago (UIC). Prior to joining UIC\, he spent two years at Post-doc Fellow at the Florida Institute for Cybersecurity (FICS) research center at the University of Florida. He received his Ph.D. degree from the University of Massachusetts Amherst in 2016 after he got the B.S. and M.S. degrees in Electrical Engineering from the University of Electronic Science and Technology of China in 2008 and 2011\, respectively. His research interests span hardware security and trust\, FPGA\, IoT security\, VLSI\, computer architecture\, embedded system\, and hardware-software co-design for modern computing systems. He is also interested in developing IoT devices and cloud-computing infrastructures with particular emphasis on security\, high-performance\, privacy protection.
URL:https://ece.northeastern.edu/event/electrical-and-computer-engineering-seminar-xiaolin-xu/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200207T110000
DTEND;TZID=America/New_York:20200207T120000
DTSTAMP:20260506T002952
CREATED:20200203T194915Z
LAST-MODIFIED:20200203T195142Z
UID:4064-1581073200-1581076800@ece.northeastern.edu
SUMMARY:Electrical and Computer Engineering Seminar: Kris Dorsey
DESCRIPTION:Location: ISEC 136 \nIt’s a bit of a stretch: selective\, flexible mechanical sensors towards VR\, healthcare\, and robotics applications \nAbstract: \nIn this talk\, Kris Dorsey will discuss work related to mechanically “programming” soft sensors to respond to a particular mechanical deformation. Advances in 3D-printing\, soft polymer fabrication\, and other rapid fabrication processes have made the vision of conformal and stretchable mechanical sensors for wearable devices and soft robotics possible. One limitation of these sensors is their low selectivity between different modes of mechanical deformation\, such as strain\, torsion\, and bending.\nShe will present recent work in enhancing the selectivity of stretchable sensors. By using non-planar sensor morphology to bias the sensor towards a particular deformation mode\, the selectivity of the sensor can be enhanced. She will discuss projects including designing a sensor with electrically-tunable sensitivity and the fabrication origami-patterned\, deformation-selective flexible sensors. \n  \nBio: \nKris Dorsey is an assistant professor of engineering in the Picker Engineering Program at Smith College. She was a President’s Postdoctoral Fellow at the University of California\, Berkeley and University of California\, San Diego. Dr. Dorsey graduated from Carnegie Mellon University with a Ph.D. in Electrical and Computer Engineering and earned her Bachelors of Science in Electrical and Computer Engineering from Olin College. \nShe founded The MicroSMITHie Lab at Smith College to investigate micro- and miniature-scale sensor design and to prepare undergraduates for graduate study in engineering. Her current research interests include strain-stable\, hyperelastic components\, novel morphology soft sensors\, and sensors for soft robots and wearable devices. \nDr. Dorsey has co-authored several publications on hyperelastic strain sensors\, novel soft lithography processes\, and the stability of gas chemical sensors. In 2019\, she received the NSF CAREER award.
URL:https://ece.northeastern.edu/event/electrical-and-computer-engineering-seminar-kris-dorsey/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200207T110000
DTEND;TZID=America/New_York:20200207T110000
DTSTAMP:20260506T002952
CREATED:20200205T004700Z
LAST-MODIFIED:20200205T004700Z
UID:4080-1581073200-1581073200@ece.northeastern.edu
SUMMARY:Electrical and Computer Engineering Seminar: Fan Zhang
DESCRIPTION:Location: ISEC 140 \nPersistent Fault Attacks in Practice \nAbstract: \nPersistent fault analysis (PFA) was proposed at CHES 2018 as a novel fault analysis technique. It was shown to completely defeat standard redundancy based countermeasure against fault analysis. The original PFA was demonstrated with rowhammer-based fault injections. However whether such an analysis can be applied to traditional microcontrollers\, together with its attack difficulty in practice\, has not been investigated. In this talk\, for the first time\, a persistent fault attack is conducted on an unprotected AES algorithm implemented on ATmega163L microcontroller. Several critical challenges are coped with our new improvements. This talk will introduce the PFA at both theoretical and practical levels. \nBio: \nDr. Fan Zhang graduated from the Department of Computer Science and Engineering\, University of Connecticut\, USA. He is currently an associate professor in the College of Computer Science\, Zhejiang University\, China. He was a visiting scholar at the National University of Singapore and currently he is a visiting professor at Singapore University of Technology and Design. His major research interest is the general cybersecurity which includes hardware security\, system security\, network security and more. His special expertise lies in the domain of side-channel attacks (SCA) and countermeasures\, fault attacks\, cryptography\, and computer architecture. He is the Program Chair of PROOFS\, TPC member of DAC\, AsiaCCS\, AsianHOST\, ASHES\, COSADE\, FDTC\, Inscrypt\, and the Associate Editor of IEEE Access\, Cybersecurity. He has more than 60 publications in international conferences and journals such as CHES\, DATE\, COSADE\, FDTC\, TIFS\, TPDS.
URL:https://ece.northeastern.edu/event/electrical-and-computer-engineering-seminar-fan-zhang/
LOCATION:140 ISEC\, 360 Huntington Ave\, 140 ISEC\, Boston\, MA\, 02115\, United States
GEO:42.3401758;-71.0892797
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END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200203T110000
DTEND;TZID=America/New_York:20200203T120000
DTSTAMP:20260506T002952
CREATED:20200128T193610Z
LAST-MODIFIED:20200203T195845Z
UID:4029-1580727600-1580731200@ece.northeastern.edu
SUMMARY:Electrical and Computer Engineering Seminar: Alper Ozgurluk
DESCRIPTION:138 ISEC \nHigh-Q Strong Coupling Capacitive-Gap Transduced RF Micromechanical Resonators \nAbstract: \nThis talk presents a hierarchical\, intuitive\, and technology agnostic procedure for designing RF channel-select filters\, followed by an actual demonstration that consists of 96 mechanically coupled capacitive-gap-transduced polysilicon disk resonators\, centered at 224MHz with only 0.1% (9kHz) bandwidth\, all while attaining 2.7dB insertion loss and more than 50dB out-of-channel stopband rejection\, solidly confirming the validity of the design method. Two distinct methods then follow that aim to increase the resonator electromechanical coupling coefficient (kt2)\, which substantially improves the functionality of the demonstrated filter for future applications\, e.g.\, ones that require higher-order with sharper roll-off characteristics and less passband ripple. Specifically\, single-digit-nanometer electrode-to-resonator gaps have enabled 200-MHz radial-contour mode polysilicon disk resonators with motional resistance Rx as low as 144Ohm while still posting Q’s exceeding 10\,000\, all with only 2.5V dc-bias. The demonstrated gap spacings down to 7.98nm are the smallest to date for upper-VHF micromechanical resonators and fully capitalize on the fourth power dependence of motional resistance on gap spacing. The scale here is perhaps best conveyed with the recognition that this gap corresponds to only 16 SiO2 molecules! \nHigh device yield and ease of measurement debunk popular prognosticated pitfalls often associated with tiny gaps\, e.g.\, tunneling\, Casimir forces\, low yield\, none of which appear. The tiny motional resistance\, together with kt2’s up to 1% at 4.7V dc-bias and kt2-Q products exceeding 100\, propel polysilicon capacitive-gap transduced resonator technology to the forefront of MEMS resonator applications that put a premium on noise performance\, such as radar oscillators. To increase functionality even further\, the rest of this talk introduces a fabrication and post-processing method using CMOS-compatible ruthenium metal that allows integration of micromechanical devices\, such as the aforementioned RF filters\, atop CMOS. To this end\, the introduction of tensile stress via localized Joule heating has yielded some of the highest metal MEMS resonator Q’s measured to date\, as high as 48\,919 for a 12-MHz ruthenium micromechanical clamped-clamped beam\, defying the common belief that metal Q cannot compete with conventional micro machinable materials. The low-temperature ruthenium metal process\, with highest temperature of 450°C and paths to an even lower ceiling of 200°C\, further allows for MEMS post-processing directly over finished foundry CMOS wafers\, thereby offering a promising route towards fully monolithic realization of CMOS-MEMS circuits\, such as needed in communication transceivers. This\, together with its higher Q\, may eventually make ruthenium metal preferable over polysilicon in some applications. \nBio: \nAlper Ozgurluk received the B.S. degree in electrical and electronics engineering from Bilkent University\, Ankara\, Turkey\, in 2012 and the Ph.D. degree in electrical engineering and computer sciences from the University of California\, Berkeley\, CA\, USA\, in 2019. The first part of his Ph.D. research focused on the design\, fabrication\, and testing of medium-scale micromechanical circuits using capacitive-gap transduced disk resonators as building blocks to demonstrate RF channel filters for ultra-low power radio applications. During his Ph.D.\, he also worked on design and fabrication methods to shrink the gaps of capacitive-gap resonators to single-digit-nanometers transforming the performance of such devices. The last part of his Ph.D. mainly focused on CMOS-compatible resonator materials and post-processing techniques that could provide decent performance much needed for CMOS-MEMS integration. In 2019\, he joined Apple Inc. as a Display Exploration Engineer.
URL:https://ece.northeastern.edu/event/electrical-and-computer-engineering-seminar-alper-ozgurluk/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200130T114500
DTEND;TZID=America/New_York:20200130T124500
DTSTAMP:20260506T002952
CREATED:20200128T193457Z
LAST-MODIFIED:20200128T193457Z
UID:4027-1580384700-1580388300@ece.northeastern.edu
SUMMARY:Electrical and Computer Engineering Seminar: Hoda Naghibijouybari
DESCRIPTION:Abstract:\nGraphics Processing Units (GPUs) are integral components to most modern computing devices\, used to optimize the performance of today’s graphics and multi-media heavy workloads. They are also increasingly integrated on heterogeneous computing servers to accelerate a broad range of applications. Meanwhile\, recent trends in security show attacks on modern systems that originate in hardware and are exploitable by software. Given the growing use of GPUs in safety-critical applications\, understanding their security properties will become a first-class design objective. \nIn this talk\, I will present my research on covert and side channel attacks and defenses in modern GPUs. I show that it is possible to construct high bandwidth covert channels\, superior in bandwidth and quality to those on CPUs. Furthermore\, I demonstrate several variants of practical side channel attacks targeting both graphics and computational workloads. The talk will also present architectural mitigations to prevent the discovered attacks. Finally\, I will conclude the talk by my planned research at the intersection of emerging architectures and security. \nBio:\nHoda Naghibijouybari is currently a Ph.D. student at the Department of Computer Science and Engineering at the University of California\, Riverside. Her research interests include architectural support for security\, GPU security\, computer architecture and heterogeneous computing. Her research has resulted in the discovery of new attacks that have been disclosed to AMD\, and Nvidia companies\, and received coverage from technical news outlets. Her paper on GPU Side Channels was one of 11 papers selected for Top Picks in Hardware and Embedded Security\, 2019 (identifying best papers in those areas in 2013-2018
URL:https://ece.northeastern.edu/event/electrical-and-computer-engineering-seminar-hoda-naghibijouybari/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200130T114500
DTEND;TZID=America/New_York:20200130T114500
DTSTAMP:20260506T002952
CREATED:20200128T193711Z
LAST-MODIFIED:20200128T193711Z
UID:4031-1580384700-1580384700@ece.northeastern.edu
SUMMARY:Electrical and Computer Engineering Seminar: Nader Sehatbakhsh
DESCRIPTION:Abstract: \nThis decade has already seen a significant surge in the number of cyber-attacks. With the exponential growth of computers in numbers\, due to the rise of cyberphysical systems (CPS) and internet-of-things (IoT) devices\, and their ever-increasing importance in controlling critical tasks\, it is expected that cybersecurity and data privacy become even more serious problems in the next decade. To this end\, I will present our methods and findings in designing secure computing systems using two main themes: 1) by discovering\, modeling\, and mitigating side-channels\, and 2) by leveraging side-channels for useful purposes such as debugging and security monitoring. Specifically\, in this talk\, I will first present our novel method on debugging and securing resource-limited devices such as embedded systems\, CPSs\, and IoTs by externally monitoring these devices using analog side-channels (e.g.\, electromagnetic emanations\, power fluctuations\, etc.) that are unintentionally created by these devices. I will describe how analog side-channel signals can be also leveraged for profiling\, intrusion detection\, and establishing a trusted execution environment (TEE) on resource constrained devices without incurring any overhead or requiring any hardware support on the monitored device and/or any intrusion to its functionality. In the second part of the talk\, I will demonstrate how we can mitigate information leakage vulnerabilities by accurately modeling analog side-channels. I will discuss our approach in designing an open-source microarchitectural simulator which can accurately simulate analog side-channel signals (electromagnetic and power side-channels) in a variety of low-end processors. I will conclude my talk by describing future directions toward secure\, private\, and remote computing systems. \nBio: \nNader Sehatbakhsh is a Ph.D. Candidate in the School of Computer Science\, Georgia Institute of Technology. His research interest is on the broad area of Security and Privacy and Computer Architecture with emphasis on hardware security\, side-channels\, hardware-support for security and privacy\, and embedded system security. His work has been published in top venues such as MICRO\, ISCA\, and HPCA\, and has been recognized with several awards and honors including the MICRO-49 Best Paper Award and Micro Top-Picks Honorable Mention.
URL:https://ece.northeastern.edu/event/electrical-and-computer-engineering-seminar-nader-sehatbakhsh/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200124T110000
DTEND;TZID=America/New_York:20200124T110000
DTSTAMP:20260506T002952
CREATED:20200121T215339Z
LAST-MODIFIED:20200121T215339Z
UID:4014-1579863600-1579863600@ece.northeastern.edu
SUMMARY:ECE Seminar: Stephanie Gil
DESCRIPTION:Abstract:  Multi-robot systems are becoming more pervasive all around us\, in the form of fleets of autonomous vehicles\, future delivery drones\, and robotic teammates for search and rescue.  As a result\, it becomes increasingly critical to question the robustness of their coordination algorithms to reliable information exchange\, security threats and/or corrupted data. This talk will focus on the role of controlled mobility and information exchange for enhancing situational awareness and security of these systems. Specifically\, we will discuss our work in using robot mobility to realize reliable and adaptive information exchange that supports coordination objectives\, the role of communication for quantifying trust in several important multi-robot algorithms\, and the use of information exchange to divulge new information about the environment.  We will study the vulnerabilities of important multi-robot algorithms such as consensus and coverage to malicious or erroneous data and we demonstrate the potential of communication to thwart certain attacks\, for example\, the Sybil Attack\, on these algorithms. We will present both a theoretical framework and experimental results\, for provably securing multi-robot distributed algorithms through careful use of communication.  Lastly\, we will present promising results on new communication-centric methods for outlier rejection and active rendezvous in distributed mapping tasks. \n  \nBio: Stephanie is an Assistant Professor in the School of Computing\, Informatics\, and Decision Systems Engineering at Arizona State University (Jan 2018). Her work centers around trust and coordination in multi-robot systems for which she has been granted an NSF CAREER award (see Improving Mission Intelligence within Fleets of Robots) and has been reviewed in MIT News (see some of her work in security for multi-robot systems and human-robot EEG based communication) as well as several other news outlets including Forbes and the Financial Times (full list on her website).  Prior\, she was a research scientist in the Computer Science and Artificial Intelligence Lab (CSAIL) at MIT where she also completed her Ph.D. work (2014) on multi-robot coordination and control and M.S. work (2009) on system identification and model learning. At MIT she collaborated extensively with the wireless communications group NetMIT\, the result of which were two U.S. patents recently awarded in adaptive heterogeneous networks for multi-robot systems and accurate indoor positioning using Wi-Fi.  She completed her B.S. at Cornell University in 2006.
URL:https://ece.northeastern.edu/event/ece-seminar-stephanie-gil/
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BEGIN:VEVENT
DTSTART;TZID=America/New_York:20200117T110000
DTEND;TZID=America/New_York:20200117T110000
DTSTAMP:20260506T002952
CREATED:20200114T230432Z
LAST-MODIFIED:20200114T230432Z
UID:4010-1579258800-1579258800@ece.northeastern.edu
SUMMARY:ECE Seminar: Siddhartha Ghosh
DESCRIPTION:Location: 136 ISEC \nAbstract: \nAcoustic waves are well-suited for a variety of signal processing applications including RF filtering and optical modulation. Advances in material and fabrication capabilities have enabled the demonstration of chip-scale subsystems in which phonons can exhibit strong interactions with a variety of other physical domains. This talk will discuss developments in two of these areas\, specifically acousto-electric (AE) amplification and acousto-optic modulation in piezoelectric materials. Recently\, non-reciprocal and switchable delay lines have generated great interest for applications in full duplex radio networks. As a result\, AEbased approaches to mitigating signal interference in the RF front end have been sought. Here we will consider the development of a low sheet density AlGaN/GaN heterostructure on sapphire substrates to demonstrate AE amplification of Rayleigh waves. In addition\, the use of atomic layer deposition (ALD) assisted wafer bonding technology is demonstrated for integrating thin film silicon on bulk lithium niobate to produce stronger non-reciprocity. These results are showcased with regard to implementation in analog correlators with large processing gain. In addition\, we will discuss the development of piezoelectrically-actuated acousto-optic modulators in the aluminum nitride (AlN) material system. Optical coupling to AlN thin films is demonstrated in the telecommunications bands\, enabling monolithic integration of photonic and bulk acoustic resonators. Overlap of these fields enables efficient conversion from RF to optical frequencies\, with applications in integrated microwave photonics and quantum information transfer. \nBio: \nSiddhartha Ghosh is currently a member of the technical staff in the RF Technology Group at MIT Lincoln Laboratory\, Lexington\, MA. He received the B.S. degree in from Cornell University in 2007\, the M.S.E. degree from the University of Pennsylvania in 2011 and the Ph.D. degree from Carnegie Mellon University in 2015\, all in electrical engineering. From 2007 to 2009 he was a Hardware Engineer with Lockheed Martin Corporation in Syracuse\, NY. He is the author of 20 journal and conference publications and coinventor of an issued patent. Since 2018\, he has served on the Technical Program Committee (TPC) for the IEEE International Frequency Control Symposium. His research interests include piezoelectric MEMS\, optomechanical resonators\, oscillator-based computing and acousto-electronic devices.
URL:https://ece.northeastern.edu/event/ece-seminar-siddhartha-ghosh/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20191211T133000
DTEND;TZID=America/New_York:20191211T133000
DTSTAMP:20260506T002952
CREATED:20191206T234804Z
LAST-MODIFIED:20191212T200023Z
UID:3985-1576071000-1576071000@ece.northeastern.edu
SUMMARY:ECE Distinguished Seminar: Clark Nguyen
DESCRIPTION:December 11th\, 2019 1:30pm \nLocation: 140 ISEC \nAbstract: \nThe use of mechanics to lower the dynamic range requirements of radio and clock receivers has recently reduced low-bit-rate communication receive power consumption to near-zero levels and stands poised to enable radio cognition for more efficient use of high-bit-rate spectrum. Approaches to cognition and power reduction go from partial-mechanical ones\, where low-capacitance integration of high Q mechanical circuits with transistors provides finer spectrum parsing to ease the burden on transistor circuits; to the latest all-mechanical topology\, where micromechanical resonant switch (a.k.a.\, resoswitch) technology enables listening for incoming signals without the need for current draw\, and ultimately only picowatts to receive and process bits once valid signals appear. \nBio: \nProf. Clark Nguyen is a Professor in the Electrical Engineering and Computer Sciences Department at the University of California at Berkeley\, where his main research thrust focuses on micromechanical signal processing. He is the Founder of Discera; served from 2002 to 2005 as a Program Manager in DARPA/MTO; and recently finished a term as President of the IEEE Ultrasonics\, Ferroelectrics\, and Frequency Control Society. He is an IEEE Fellow and recipient of the 2006 IEEE Cady Award and the 2017 IEEE Bosch MEMS Award.
URL:https://ece.northeastern.edu/event/ece-distinguished-seminar-clark-nguyen/
LOCATION:140 ISEC\, 360 Huntington Ave\, 140 ISEC\, Boston\, MA\, 02115\, United States
GEO:42.3401758;-71.0892797
X-APPLE-STRUCTURED-LOCATION;VALUE=URI;X-ADDRESS=140 ISEC 360 Huntington Ave 140 ISEC Boston MA 02115 United States;X-APPLE-RADIUS=500;X-TITLE=360 Huntington Ave\, 140 ISEC:geo:-71.0892797,42.3401758
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20191113T120000
DTEND;TZID=America/New_York:20191113T133000
DTSTAMP:20260506T002952
CREATED:20191108T205935Z
LAST-MODIFIED:20191108T205935Z
UID:3949-1573646400-1573651800@ece.northeastern.edu
SUMMARY:ECE Distinguished Speaker Series: David Z. Pan; Wednesday\, November 13 at 12 PM in 140 ISEC
DESCRIPTION:Abstract: \nThe recent artificial intelligence (AI) boom has been largely driven by three confluence forces: algorithms\, big data\, and computing power enabled by modern integrated circuits (ICs) including specialized AI accelerators. In this talk\, I will present a synergistic approach on AI and intelligent IC/accelerator designs with two main themes\, AI for IC and IC for AI. As the semiconductor technology enters the era of extreme scaling\, IC design and manufacturing complexities are becoming extremely high. More intelligent and agile IC design technologies are needed than ever to optimize performance\, power\, area\, manufacturability\, reliability\, security\, etc.\, and to deliver equivalent scaling to Moore’s Law. I will present some recent results leveraging modern AI and machine learning advancement with domain-specific customizations for agile IC design and manufacturing closure. Meanwhile\, customized IC can drastically improve AI performance and energy efficiency by orders of magnitude. I will present the hardware/software co-design for energy-efficient neural networks. The bidirectional reinforcement of AI and IC technologies holds great potential to significantly advance the state-of-the-art of each other. \nBio: \nDavid Z. Pan received his BS degree in Physics from Peking University and his MS/PhD degrees in Computer Science from UCLA. From 2000 to 2003\, he was a Research Staff Member with the IBM T. J. Watson Research Center. He is an Engineering Foundation Professor at the Department of Electrical and Computer Engineering\, University of Texas at Austin. He is also currently a Visiting Professor/Scientist at MIT EECS/MTL.  His research interests include bidirectional AI and IC interaction\, cross-layer design for manufacturability\, reliability\, security\, CAD for analog/mixed-signal designs and emerging technologies. He has published over 350 refereed journal/conference papers and 8 US patents. He has served in many journal editorial boards and conference committees\, including various leadership roles. He is the ACM/SIGDA Award Chair. \nHe has received 17 Best Paper Awards and 13 additional Best Paper Award nominations. He is a Fellow of IEEE and SPIE.
URL:https://ece.northeastern.edu/event/ece-distinguished-speaker-series-david-z-pan-wednesday-november-13-at-12-pm-in-140-isec/
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=America/New_York:20191017T103000
DTEND;TZID=America/New_York:20191017T103000
DTSTAMP:20260506T002952
CREATED:20191008T175550Z
LAST-MODIFIED:20191010T182820Z
UID:3872-1571308200-1571308200@ece.northeastern.edu
SUMMARY:ECE Distinguished Guest Speaker Series: Advanced Control of Energy Related Infrastructure
DESCRIPTION:ECE Distinguished Guest Speaker Series\nJakob Stoustrup\, Aalborg University\nAdvanced control of energy related infrastructure\nThursday\, October 17\n142 ISEC 10:30 am \nAbstract:\nIn pursuit of solutions for a sustainable energy system\, control engineering has several key roles to play. It is generally recognized that an energy system that includes substantial contributions from PV systems and wind farms\, will have to leverage synergy between different types of energy related infrastructure (electricity\, heating/cooling\, gas\, the water/energy nexus\, transportation\, etc.). The synergy will be instrumented by storage and conversion technologies\, but orchestrated by advanced control systems that do not exist today. Furthermore\, usage of e.g. power and heat on the consumer side needs to be coordinated\, also through advanced control. Finally\, the electricity system itself needs to be instrumented with entirely new types of control\, where especially the distribution system is in need for new control architectures. \nIn this talk\, we will present examples of current research at all three types of roles for advanced control related to challenges for a sustainable energy system. This talk will present some of the challenges for power distribution systems along with some solutions. Further\, results from our research on integrating power and heat solutions will be presented. Finally\, research on consumer side control challenges will be presented with a case study for heat and power control of shopping malls. \nBio:\nJakob Stoustrup has received M.Sc. (EE\, 1987) and Ph.D. (Applied Mathematics\, 1991) degrees\, both from the Technical University of Denmark. From 1991-1996\, Stoustrup held several positions at Department of Mathematics\, Technical University of Denmark. From 2006-2013 he acted as Head of Research for Department of Electronic Systems\, Aalborg University. From 2014-2016\, Stoustrup was Chief Scientist at Pacific Northwest National Laboratory\, USA\, leading the Control of Complex Systems Initiative. From 1997-2013 and since 2016\, Stoustrup has acted as Professor at Automation & Control\, Aalborg University\, Denmark. In 2017 Stoustrup was appointed as Vice Dean at the Technical Faculty of IT and Design\, Aalborg University. \nDr. Stoustrup has acted as Associate Editor and Editorial Board Member of several international journals. Served as General Chair\, Program Chair\, and IPC member for several international conferences. Member of the IEEE CSS Board of Governors. Past Chairman of IEEE CSS/RAS Joint Chapter. Chair for IEEE CSS Technical Committee on Smart Grids. Chair for IFAC Technical Committee SAFEPROCESS\, and Member of IFAC Technical Board. Received the Statoil Prize\, the Dannin Award for Scientific Research and several conference paper awards. He received the Chivalric Order of the Dannebrog for his research contributions. Member of the European Research Council as well as the Danish\, Norwegian and Swedish Research Councils. He is a member of The Danish Academy of Technical Sciences\, where he has acted as Board Member. \nStoustrup’s main contributions have been to robust control theory and to the theory of fault tolerant control systems. With co-workers\, he has proposed a novel Plug-and-Play Control framework. Published approx. 300 peer-reviewed scientific papers. Apart from the theoretical work\, he has been involved in applications in cooperation with 100+ industrial companies\, including acting as CEO for two technological startup companies.
URL:https://ece.northeastern.edu/event/ece-seminar-advanced-control-of-energy-related-infrastructure/
LOCATION:142 ISEC\, 360 Huntington Ave\, 142 ISEC\, Boston\, MA\, 02115\, United States
GEO:42.3401758;-71.0892797
X-APPLE-STRUCTURED-LOCATION;VALUE=URI;X-ADDRESS=142 ISEC 360 Huntington Ave 142 ISEC Boston MA 02115 United States;X-APPLE-RADIUS=500;X-TITLE=360 Huntington Ave\, 142 ISEC:geo:-71.0892797,42.3401758
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END:VCALENDAR