BEGIN:VCALENDAR VERSION:2.0 PRODID:-//Northeastern University College of Engineering - ECPv6.15.18//NONSGML v1.0//EN CALSCALE:GREGORIAN METHOD:PUBLISH X-WR-CALNAME:Northeastern University College of Engineering X-ORIGINAL-URL:https://coe.northeastern.edu X-WR-CALDESC:Events for Northeastern University College of Engineering REFRESH-INTERVAL;VALUE=DURATION:PT1H X-Robots-Tag:noindex X-PUBLISHED-TTL:PT1H BEGIN:VTIMEZONE TZID:America/New_York BEGIN:DAYLIGHT TZOFFSETFROM:-0500 TZOFFSETTO:-0400 TZNAME:EDT DTSTART:20200308T070000 END:DAYLIGHT BEGIN:STANDARD TZOFFSETFROM:-0400 TZOFFSETTO:-0500 TZNAME:EST DTSTART:20201101T060000 END:STANDARD BEGIN:DAYLIGHT TZOFFSETFROM:-0500 TZOFFSETTO:-0400 TZNAME:EDT DTSTART:20210314T070000 END:DAYLIGHT BEGIN:STANDARD TZOFFSETFROM:-0400 TZOFFSETTO:-0500 TZNAME:EST DTSTART:20211107T060000 END:STANDARD BEGIN:DAYLIGHT TZOFFSETFROM:-0500 TZOFFSETTO:-0400 TZNAME:EDT DTSTART:20220313T070000 END:DAYLIGHT BEGIN:STANDARD TZOFFSETFROM:-0400 TZOFFSETTO:-0500 TZNAME:EST DTSTART:20221106T060000 END:STANDARD END:VTIMEZONE BEGIN:VEVENT DTSTART;TZID=America/New_York:20210629T110000 DTEND;TZID=America/New_York:20210629T120000 DTSTAMP:20260405T044543 CREATED:20210623T171312Z LAST-MODIFIED:20210623T171312Z UID:26363-1624964400-1624968000@coe.northeastern.edu SUMMARY:ECE PhD Dissertation Defense: Yaoshen Yuan DESCRIPTION:PhD Dissertation Defense: Enhancing Monte Carlo Light Modeling Methods for the Development of Near-infrared Based Brain Techniques \nYaoshen Yuan \nLocation: Zoom Link \nAbstract: Studying light propagation in biological tissues is critical for developing biophotonics techniques and its applications. Monte Carlo (MC) method\, a stochastic solver for radiative transfer equation\, has been recognized as the gold standard for modeling light propagation in turbid media. However\, due to the stochastic nature of MC method\, millions even billions of photons are usually required to achieve accurate results using MC method\, leading to a long computational time even with the acceleration using graphical processing units (GPU).\nFurthermore\, due to the rapid advances in multi-scale optical imaging techniques such as optical coherence tomography (OCT) and multiphoton microscopy (MPM)\, there is an increasing need to model light propagation in extremely complex tissues such as vessel networks. The mesh-based Monte Carlo (MMC) is usually superior than the voxel-based MC method for such modeling since unlike grid-like voxels\, tetrahedral meshes can represent arbitrary shapes with curved boundaries. However\, the mesh density can be excessively high when the tissue structure is extremely complex\, resulting in high computational costs and memory demand.\nThe goal of this proposal is to focus on solving the challenges mentioned above. To tackle the first challenge\, we came up with a filtering approach with GPU acceleration to improve the signal-to-noise ratio (SNR) of the results while keeping the simulated photons low. The adaptive non-local means (ANLM) filter is selected to suppress the stochastic noise in MC results because 1) the filtering process on each voxel is mutually independent\, making it possible for parallel computing; 2) it has high performance in denoising and a strong capacity in edge-preserving.\nFor the second problem\, a novel method\, implicit mesh-based Monte Carlo (iMMC)\, was proposed to significantly reduce the mesh density. The iMMC utilizes the edge\, node and face of the tetrahedral mesh to model tissue structures with shapes of cylinder\, sphere and thin layer. The typical applications for edge\, node and face-based iMMC are vessel networks\, porous media and membranes\, respectively.\nLastly\, we applied MC simulations and aforementioned filter on segmented brain models derived from MRI neurodevelopmental atlas to estimate the light dosage for transcranial photobiomodulation (t-PBM)\, a technique for treating major depressive disorder using near infrared\, across lifespan. The iMMC simulation was also applied to evaluate the impact of human hair on the brain sensitivity for functional near-infrared spectroscopy (fNIRS). Furthermore\, a new approach that can improve the penetration depth in optical brain imaging as well as PBM is proposed. In this approach\, the possibility of placing light sources in head cavities is investigated using MC simulations. The preliminary results demonstrate a better performance in deep brain monitoring compared to the standard transcranial approach using 10-20 EEG positioning system. URL:https://coe.northeastern.edu/event/ece-phd-dissertation-defense-yaoshen-yuan-2/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210701T110000 DTEND;TZID=America/New_York:20210701T120000 DTSTAMP:20260405T044543 CREATED:20210623T171449Z LAST-MODIFIED:20210623T171449Z UID:26361-1625137200-1625140800@coe.northeastern.edu SUMMARY:ECE PhD Dissertation Defense: Xianfeng Liang DESCRIPTION:PhD Dissertation Defense: RF Magnetoelectric Microsystems \nXianfeng Liang \nLocation: Zoom Link \nAbstract: Multiferroic materials are the materials that inherently exhibit two or more ferroic properties\, such as ferroelectricity\, ferromagnetism and ferroelasticity\, etc. Magnetoelectric (ME) materials with coupled magnetization and electric polarization have attracted intense interests recently due to the realization of strong ME coupling and their key roles inME applications. Since the revival of thin-film ME heterostructures with giant ME coefficients\, a variety of multifunctional ME devices\, such as sensors\, inductors\, filters\, antennas etc. have been developed. Exciting progress has been made on novel ME materials and devices because of their high-performance ME coupling.\nIn this dissertation\, we will first show the properties of magnetostrictive (FeGaC and SmFe) and piezoelectric (ZnO)thin-film materials that are necessary for realizing strong ME coupling. A systematic investigation of the soft magnetism\, the change of modulus of elasticity with magnetization (delta-E effect)\, and microwave properties was carried out on FeGaC and SmFe thin films. We successfully developed the magnetostrictive FeGaC thin films with low coercive field of less than 1 Oe\, high saturation magnetization\, narrow ferromagnetic resonance (FMR) linewidth\, and an ultra-low Gilbert damping constant of 0.0027. A record high piezomagnetic coefficient of 9.71 ppm/Oe\, high saturation magnetostriction constant of 81.2 ppm\, and large delta-E effect of -120 GPa at 500 nm were achieved. ZnO films with high c-axis crystal orientation was also achieved by carefully optimizing the sputtering process parameters. These properties make them attractive materials for magnetoelectric and other voltage tunable RF/microwave device applications.\nAfter presenting the magnetostrictive and piezoelectric thin films and their static and dynamic properties\, we introduce the radio frequency (RF) ME microsystems. Mechanically driven antennas have been demonstrated to be the most effective method to miniaturize antennas compared to state-of-the-art compact antennas.The ME antennas based on a released magnetostrictive/piezoelectric heterostructure rely on electromechanical resonance instead of electromagnetic wave resonance\, which results in an antenna size as small as one-thousandth of an electromagnetic wavelength. Due to the strong ME coupling in thin-film ME heterostructures\, we proposed the ultra-compact MEMS ME antennas and improved their performance by using anchor designs\, array structure\, and SMR structure. These miniaturized robustME antennas can be implemented in numerous real-world applications such as internet of things\, wearable and bio-implantable devices\, smart phones\, wireless communication systems\, etc. The ME antennas\, with an overall dimension of 700 m×700 m (L×W)\, were designed to operate at a resonant frequency of 2 GHz and experimentally demonstrated a gain of -18.85 dBi. Furthermore\, we demonstrated highly sensitive integrated RF giant magnetoimpedance (GMI)sensors based on amplitude and phase sensitive mechanisms. The amplitude and phase magnetic noise levels were demonstrated to be 810pT /√Hz at 1000 Hz and 100pT /√Hz\, respectively. URL:https://coe.northeastern.edu/event/ece-phd-dissertation-defense-xianfeng-liang/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210707T140000 DTEND;TZID=America/New_York:20210707T150000 DTSTAMP:20260405T044543 CREATED:20210706T135010Z LAST-MODIFIED:20210706T135010Z UID:26505-1625666400-1625670000@coe.northeastern.edu SUMMARY:ECE PhD Proposal Review: Xiaolong Ma DESCRIPTION:PhD Proposal Review: Towards Efficient Deep Neural Network Execution with Model Compression and Platform-specific Optimization \nXiaolong Ma \nLocation: Zoom \nAbstract: Deep learning or deep neural networks (DNNs) have become the fundamental element and core enabler of ubiquitous artificial intelligence. Recently\, with the emergence of a spectrum of high-end mobile devices\, many deep learning applications that formerly required desktop-level computation capability are being transferred to these devices. However\, executing DNN inference is still challenging considering the high computation and storage demands\, specifically\, if real-time performance with high accuracy is needed. Weight pruning of DNNs is proposed\, but existing schemes represent two extremes in the design space: non-structured pruning is fine-grained\, accurate\, but not hardware friendly; structured pruning is coarse-grained\, hardware-efficient\, but with higher accuracy loss. To solve the problem\, we propose a compression-compilation co-optimization framework\, which includes 1) a new dimension\, fine-grained pruning patterns inside the coarse-grained structures that achieves accuracy enhancement and preserve the structural regularity that can be leveraged for hardware acceleration\, 2) a pattern-aware pruning framework that achieves pattern library extraction\, pattern selection\, pattern and connectivity pruning and weight training simultaneously\, and 3) a set of thorough architecture-aware compiler/code generation-based optimizations\, i.e.\, filter kernel reordering\, compressed weight storage\, register load redundancy elimination\, and parameter auto-tuning for real-time execution of the mainstream DNN applications on the mobile platforms. Evaluation results demonstrate that our framework outperforms three state-of-the-art end-to-end DNN frameworks\, TensorFlow Lite\, TVM\, and Alibaba Mobile Neural Network with speedup up to 44.5x\, 11.4x\, and 7.1x\, respectively\, with no accuracy compromise. Real-time inference of representative large-scale DNNs (e.g.\, VGG-16\, ResNet-50) can be achieved using mobile devices. URL:https://coe.northeastern.edu/event/ece-phd-proposal-review-xiaolong-ma/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210707T170000 DTEND;TZID=America/New_York:20210707T180000 DTSTAMP:20260405T044543 CREATED:20210706T135131Z LAST-MODIFIED:20210706T135131Z UID:26484-1625677200-1625680800@coe.northeastern.edu SUMMARY:ECE PhD Dissertation Defense: Kaidi Xu DESCRIPTION:PhD Dissertation Defense: Can We Trust AI? Towards Practical Implementation and Theoretical Analysis in Trustworthy Machine Learning \nKaidi Xu \nLocation: Zoom Link \nAbstract: Deep learning has achieved extraordinary performance in many application domains recently. It has been well accepted that DNNs are vulnerable to adversarial attacks\, which raises concerns of DNNs in security-critical applications and may result in disastrous consequences. Adversarial attacks are usually implemented by generating adversarial examples\, i.e.\, adding sophisticated perturbations onto benign examples\, such that adversarial examples are classified by the DNN as target (wrong) labels instead of the correct labels of the benign examples. The adversarial machine learning aims to study this phenomenon and leverage it to build robust machine learning systems and explain DNNs.\nIn this talk\, I will present the mechanism of adversarial machine learning in both empirical and theoretical ways. Specifically\, a uniform adversarial attack generation framework\, structured attack (StrAttack) is introduced\, which explores group sparsity in adversarial perturbations by sliding a mask through images aiming for extracting key spatial structures. Second\, we discuss the feasibility of adversarial attacks in the physical world and introduce a convincing framework\, Expectation over Transformation (EoT). Utilize EoT with Thin Plate Spline (TPS) transformation\, we can generate Adversarial T-shirts\, a powerful physical adversarial patch for evading person detectors even if it could undergo non-rigid deformation due to a moving person’s pose changes. Third\, we stand on the defense side and design the first adversarial training method based on Graph Neural Network. Finally\, we introduce Linear relaxation-based perturbation analysis (LiRPA) for neural networks\, which computes provable linear bounds of output neurons given a certain amount of input perturbation. LiRPA studies the adversarial example in a theoretical way and can guarantee the test accuracy of a model by given perturbation constraints. The generality\, flexibility\, efficiency and ease-of-use of our proposed framework facilitate the adoption of LiRPA based provable methods for other machine learning problems beyond robustness verification URL:https://coe.northeastern.edu/event/ece-phd-dissertation-defense-kaidi-xu/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210713T100000 DTEND;TZID=America/New_York:20210713T110000 DTSTAMP:20260405T044543 CREATED:20210706T134832Z LAST-MODIFIED:20210706T134832Z UID:26507-1626170400-1626174000@coe.northeastern.edu SUMMARY:ECE PhD Dissertation Defense: Maher Kachmar DESCRIPTION:PhD Dissertation Defense: Active Resource Partitioning and Planning for Storage Systems using Time Series Forecasting and Machine Learning Techniques \nMaher Kachmar \nLocation: Zoom \nAbstract: In today’s enterprise storage systems\, supported data services such as snapshot delete or drive rebuild can result in tremendous performance overhead if executed inline along with heavy foreground IO\, often leading to missing Service Level Objectives (SLOs). Moreover\, new classes of data services\, such as thin provisioning\, instant volume snapshots\, and data reduction features make capacity planning and drive wear-out prediction quiet challenging. Having enough free storage pool capacity available ensures that the storage system operates in favorable conditions during heavy foreground IO cycles. This enables the storage system to defer background work to a future idle cycle. Static partitioning of storage systems resources such as CPU cores or memory caches may lead to missing data reduction rate (DRR) guarantees. However\, typical storage system applications such as Virtual Desktop Infrastructure (VDI) or web services follow a repetitive workload pattern that can be learned and/or forecasted. Learning these workload pattern allows us to address several storage system resource partitioning and planning challenges that may not be overcome with traditional manual tuning and primitive feedback mechanism.\nFirst\, we propose a priority-based background scheduler that learns this pattern and allows storage systems to maintain peak performance and meet service level objectives (SLOs) while supporting a number of data services. When foreground IO demand intensifies\, system resources are dedicated to service foreground IO requests. Any background processing that can be deferred is recorded to be processed in future idle cycles\, as long as our forecaster predicts that the storage pool has remaining capacity. A smart background scheduler can adopt a resource partitioning model that allows both foreground and background IO to execute together\, as long as foreground IOs are not impacted\, harnessing any free cycles to clear background debt. Using traces from VDI and web services applications\, we show how our technique can out-perform a static policy that sets fixed limits on the deferred background debt and reduces SLO violations from 54.6% (when using a fixed background debt watermark)\, to only 6.2% when employing our dynamic smart background scheduler.\nSecond\, we propose a smart capacity planning and recommendation tool that ensures the right number of drives are available in the storage pool in order to meet both capacity and performance constraints\, without over-provisioning storage. Equipped with forecasting models that characterize workload patterns\, we can predict future storage pool utilization and drive wear-outs. Similarly\, to meet SLOs\, the tool recommends expanding pool space in order to defer more background work through larger debt bins. Overall\, our capacity planning tool provides a day/hour countdown for the next Data Unavailability/Data Loss (DU/DL) event\, accurately predicting DU/DL events to cover a future 12-hour time window.\nMoreover\, supported services such as data deduplication are becoming a common feature adopted in the data center\, especially as new storage technologies mature. Static partitioning of storage system resources\, memory caches\, may lead to missing SLOs\, such as the Data Reduction Rate (DRR) or IO latency. Lastly\, we propose a Content-Aware Learning Cache (CALC) that uses online reinforcement learning models (Q-Learning\, SARSA and Actor-Critic) to actively partition the storage system cache between a deduplicated data digest cache\, content cache\, and address-based data cache to improve cache hit performance\, while maximizing data reduction rates. Using traces from popular storage applications\, we show how our machine learning approach is robust and can out-perform an iterative search method for various data-sets and cache sizes. Our content-aware learning cache improves hit rates by 7.1% when compared to iterative search methods\, and 18.2\% when compared to traditional LRU-based data cache implementation. URL:https://coe.northeastern.edu/event/ece-phd-dissertation-defense-maher-kachmar/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210719T113000 DTEND;TZID=America/New_York:20210719T123000 DTSTAMP:20260405T044543 CREATED:20210713T172719Z LAST-MODIFIED:20210713T172719Z UID:26599-1626694200-1626697800@coe.northeastern.edu SUMMARY:ECE PhD Dissertation Defense: Berkan Kadioglu DESCRIPTION:PhD Dissertation Defense: An Analysis of Algorithms with Discrete Choice Models \nBerkan Kadioglu \nLocation: Zoom Link \nAbstract: In the first half of our work\, we consider a rank regression setting\, in which a dataset of $N$ samples with features in $\mathbb{R}^d$ is ranked by an oracle via $M$ pairwise comparisons.\nSpecifically\, there exists a latent total ordering of the samples; when presented with a pair of samples\, a noisy oracle identifies the one ranked higher w.r.t. the underlying total ordering.\nA learner observes a dataset of such comparisons\, and wishes to regress sample ranks from their features.\nWe show that to learn the model parameters with $\epsilon > 0$ accuracy\, it suffices to conduct $M \in \Omega(dN\log^3 N/\epsilon^2)$ comparisons uniformly at random when $N$ is $\Omega(d/\epsilon^2)$.\nCompared to learning from class labels\, learning from comparison labels has two advantages: First\, comparison labels reveal both inter and intra-class information\, where class labels only contain the former.\nSecond\, comparison labels also exhibit lower variability across different labelers.\nThis has been observed experimentally in multiple domains\, including medicine \citep{campbell2016plus\,kalpathy2016plus\, stewart2005absolute} and recommendation systems \citep{schultz2004learning\,zheng2009mining\,brun2010towards\, koren2011ordrec}\, and is due to the fact that humans often find it easier to make relative\, rather than absolute\, judgements.\nMany works focusing on empirically learning comparison labels show excellent performance in practice \citep{tian2019severity\,yildiz2019classification}.\nOur work provides a theoretical foundation for analyzing and understanding this empirical performance.\nMoreover\, we extend the problem we initially study to a harder setting.\nWe do this by moving from pairwise comparisons to multi-way comparisons.\nFurthermore\, we study an online variant of the previous problem where the goal is to maintain high user engagement throughout the learning period.\nThis of course\, indirectly leads to the goal of learning parameters of the discrete choice model as accurately as possible\, fast.\nThis new problem is directly related to a setting in which a retailer recommends products to customers.\nA common problem in many recommendation tasks is to simultaneously learn the utilities of items to be recommended and maintain high user engagement.\nWe are generally constrained by a limit on the total number of items to be recommended at a time for an unknown time horizon.\nRecently\, bandit algorithms have been proposed for this setting where the multinomial logit model is assumed.\nBounds on error metrics are provided for upper confidence and Thompson sampling based algorithms.\nIn our paper\, we propose a variational inference based Thompson sampling algorithm and identify the required properties to achieve $\tilde O(D^{3/2}\sqrt T)$ worst-case regret.\nThrough extensive experiments we show that our method performs much better than the recently proposed \emph{TSMNL} algorithm in many error metrics.\nWe further accelerate our algorithm to be used in practical settings. URL:https://coe.northeastern.edu/event/ece-phd-dissertation-defense-berkan-kadioglu/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210720T080000 DTEND;TZID=America/New_York:20210722T130000 DTSTAMP:20260405T044543 CREATED:20210621T200006Z LAST-MODIFIED:20210621T200006Z UID:26347-1626768000-1626958800@coe.northeastern.edu SUMMARY:COE CommLab/Khoury College Writing Retreat DESCRIPTION:College of Engineering PhD students are invited to join us for a writing retreat July 20 – 22.  The aim of this retreat is to create sustained writing time for researchers to work in a calm\, supportive environment on a longer project.  Studies have shown that an academic writing retreat supports productivity and progress while also encouraging helpful guidance from peers. \nOur virtual retreat is organized around alternating periods of quiet work on individual projects with collective sessions on topics related to research writing. Each of the three days begins with a welcome message and group gathering. On the last day\, we’ll wrap up the retreat with a virtual lunch to share concluding thoughts. \nRegister here for this event by June 24. URL:https://coe.northeastern.edu/event/coe-commlab-khoury-college-writing-retreat/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210723T100000 DTEND;TZID=America/New_York:20210723T110000 DTSTAMP:20260405T044543 CREATED:20210706T205406Z LAST-MODIFIED:20210706T205406Z UID:26516-1627034400-1627038000@coe.northeastern.edu SUMMARY:ECE PhD Dissertation Defense: Mahmoud Ibrahim DESCRIPTION:PhD Dissertation Defense: Low-Power Integrated Circuit Design for Wireless Devices in the Internet of Things \nMahmoud Ibrahim \nLocation:  Zoom \nAbstract: Numerous integrated sensing devices are under development for wireless medical diagnostic and monitoring applications. However\, the data rates of wireless devices connected to the Internet of Things are limited and strongly depend on the available power. This research addresses the need for circuit-level design methods to enable higher data rates with lower power consumption in order to facilitate the proliferation of wireless devices that can overcome the speed-power conundrum. The potential applications include continuous-time monitoring of physiological signals\, where increased data rates imply the ability to exchange more information during the same time\, more accurate data\, and/or data from a greater number of sites associated with each wireless node.\nAn energy-efficient binary frequency shift keying (BFSK) transmitter architecture for biomedical applications is introduced as the first part of this dissertation research. To achieve low power consumption with higher data rates\, the novel transmitter architecture leverages image rejection techniques to generate each of the two tones of the transmitted BFSK signal while keeping the phase-locked loop (PLL) oscillator frequency unchanged\, and thus maintaining low PLL power and overall transmitter power. A fabricated prototype chip in 130nm complementary metal-oxide-semiconductor (CMOS) technology achieves data rates up to 10 Mbps while consuming 180 µW with up to -20 dBm output power according to Medical Implant Communication System (MICS) band requirements. The measurement results confirm state-of-the-art energy-efficient performance with 18 pJ/bit.\nAs a natural continuation of the first part of this research\, a complementary receiver architecture is described in the second part of this dissertation to provide full transceiver capabilities. The new receiver design approach takes advantage of the transmitted signal characteristics by using both the frequency information and phase information to demodulate the received digital bits. This design method results in improved sensitivity with reduced power consumption through relaxed receiver block specification requirements. The custom-designed receiver circuits include a new low-noise amplifier (LNA) topology for energy-efficient antenna impedance matching\, and a single mixer circuit that realizes the signal down-conversion with differential in-phase and quadrature-phase baseband output signals to circumvent the complexity associated with two mixers and to save power. Measurement results of the fabricated receiver in 65nm CMOS technology show a sensitivity of -82 dBm with an input signal at 10 Mbps centered around 416 MHz. With a power consumption of 610 µW and an energy efficiency of 61 pJ/bit\, this receiver architecture displays state-of-the-art performance with respect to data rate\, power and sensitivity compared to other receivers in the same frequency range.\nIn addition to the new transmitter and receiver architectures\, a large-signal transconductance linearization technique is presented as part of this dissertation research to extend the dynamic range of analog baseband filters. Furthermore\, a low-power sinusoidal signal generation technique is introduced and analyzed\, which is a versatile and essential component of the transmitter design approach. URL:https://coe.northeastern.edu/event/ece-phd-dissertation-defense-mahmoud-ibrahim/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210728T140000 DTEND;TZID=America/New_York:20210728T150000 DTSTAMP:20260405T044543 CREATED:20210727T151651Z LAST-MODIFIED:20210727T151651Z UID:26729-1627480800-1627484400@coe.northeastern.edu SUMMARY:ECE PhD Proposal Review: Bahare Azari DESCRIPTION:PhD Proposal Review: Circular-Symmetric Correlation Layer based on FFT \nBahare Azari \nLocation: Zoom Link \nAbstract: Planar convolutional neural networks\, widely known as CNNs\, have been exceptionally successful in many computer vision and machine learning tasks\, such as object detection\, tracking\, and classification. The convolutional layers in CNN are characterized by pattern-matching filters that can identify motifs in the signal residing on a 2D plane. However\, there exists various applications in which we have signals lying on a curved manifold or an arbitrary collection of coordinates\, e.g.\, temperature and climate data on the surface of the (spherical) earth\, and 360-panoramic images acquired from LiDAR. In these applications\, we usually need our network to be equivariant/invariant to various transformations of the input\, i.e.\, as we transform the input according to a certain action of a group\, the output is respectively transformed (equivariance)\, or remains unchanged (invariance). The convolution layers are empirically known to be invariant to small translations of their input image\, but they are not completely immune to relatively large translations Hence\, they may fail on the tasks that requires invariance to a specific transformation\, and and on the data that includes a wide range of that transformation. \nIn this work we consider equivariant/invariant tasks on 360-panoramic data. For a systematic treatment of analyzing the 360-panoramic data\, we propose a circular-symmetric correlation Layer (CCL) based on the formalism of roto-translation equivariant correlation on the continuous group constructed of the unit circle and the real line. We implement this layer efficiently using the well-known Fast Fourier Transform (FFT) and discrete cosine transform (DCT) algorithm. We discuss how the FFT yields the exact calculation of the correlation along the panoramic direction due to the circular symmetry and guarantees the invariance with respect to circular shift. The DCT provides an improved approximation with respect to transnational symmetry compared to what we observe in CNNs. We demonstrated the invariance analysis of networks built with CCL on two benchmark datasets comparing the equivariance of neural networks adopting CCL layers and regular CNN. Then\, we showcase the performance analysis of a general network equipped with CCL on recognition and classification tasks\, such as panoramic scene change detection\, 3D object classification\, LIDAR Semantic Segmentation. URL:https://coe.northeastern.edu/event/ece-phd-proposal-review-bahare-azari/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210728T160000 DTEND;TZID=America/New_York:20210728T170000 DTSTAMP:20260405T044543 CREATED:20210726T142333Z LAST-MODIFIED:20210726T142333Z UID:26717-1627488000-1627491600@coe.northeastern.edu SUMMARY:COE CommLab Research Dissemination Series: Preprints Workshop DESCRIPTION:Do you have a fully drafted journal article ready to share with other researchers that you want to share before the traditional peer review process is done? \nPreprinting is one way to disseminate your research almost immediately.  Join the Northeastern COE Communication Lab for a workshop discussing the importance of preprints and open science.  We will cover the basics of preprints and address common concerns about preprinting. \nRegister via Zoom URL:https://coe.northeastern.edu/event/coe-commlab-research-dissemination-series-preprints-workshop/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210729T150000 DTEND;TZID=America/New_York:20210729T160000 DTSTAMP:20260405T044543 CREATED:20210727T151933Z LAST-MODIFIED:20210727T151933Z UID:26735-1627570800-1627574400@coe.northeastern.edu SUMMARY:ECE PhD Proposal Review: Weite Zhang DESCRIPTION:PhD Proposal Review: High Sensing-capacity Multi-dimensional-coded Millimeter-wave MIMO Imaging System \nWeite Zhang \nLocation: Microsoft Teams Link \nAbstract: Millimeter-wave (mm-wave) MIMO imaging systems have been explored to use more and more complicated radar waveforms to achieve advanced multiplexing and high-performance imaging. As the complexity of the radar waveform increases\, conventional systems inevitably suffer from higher design difficulty and cost. In spite of the radar waveform design\, existing mm-wave imaging systems are still suboptimal due to the fact that the sensing matrix is not tailored properly to achieve its maximum capacity\, which often results in large mutual information between successive measurements\, and limited imaging performance.\nAs the first contribution of this proposal\, high sensing-capacity mm-wave MIMO imaging systems with multi-dimensional-coding are built. In the first prototype\, a 70-77 GHz frequency-modulated continuous wave (FMCW) MIMO imaging system with massive channels is studied. To enhance the sensing-capacity\, a compressive reflector antenna (CRA) is added to perform randomized spatial wavefront coding to increase the measurement diversity. Both static and on-the-move experiments are carried out to show the functionality of the imaging system. In the second prototype\, an 81-86 GHz software-defined mm-wave MIMO imaging system is designed\, which makes use of cost-effective software-defined radios (SDRs) with mm-wave mixers. Due to the baseband flexibility of SDRs\, efficient orthogonal frequency-division multiplexing (OFDM) with binary phase coding is designed as the radar waveform to achieve simultaneous MIMO transmission\, where high receiving signal-to-noise ratio and spectrum efficiency are achieved. Again\, a CRA is designed and applied to increase the measurement diversity. Primary simulation and experimental results show good imaging performance with reduced side lobe effect.\nAs the second contribution of this proposal\, a material characterization method is developed\, which is vital in some important mm-wave imaging applications\, such as security screening\, where both object profile and material information are required for potential threats prediction. Specifically\, a Geometrical Optics (GO) forward model based on a reflectarray imaging system is developed. The GO forward model can be adapted to any other imaging systems as long as their geometrical configurations are known. Both simulations and experiments are performed to show the effectiveness and efficiency of the proposed material characterization method\, where the complex relative permittivity as well as a more accurate shape of the object is retrieved. URL:https://coe.northeastern.edu/event/ece-phd-proposal-review-weite-zhang/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210802T140000 DTEND;TZID=America/New_York:20210802T150000 DTSTAMP:20260405T044543 CREATED:20210729T145822Z LAST-MODIFIED:20210729T145822Z UID:26761-1627912800-1627916400@coe.northeastern.edu SUMMARY:ECE PhD Dissertation Defense: Yulun Zhang DESCRIPTION:PhD Dissertation Defense: Deep Convolutional Neural Network for Image Restoration and Synthesis \nYulun Zhang \nLocation: Zoom Link \nAbstract: Image restoration and synthesis with deep learning play a fundamental role in the computer vision community. They are widely used on mobile devices (e.g.\, smartphones) or lead to billion-dollar startups. However\, how to design efficient deep convolutional neural networks (CNNs) to extract higher-quality deep CNN features for better image restoration and synthesis is still challenging. In this dissertation talk\, I will describe my recent works to enhance CNN features in the channel dimension or/and the spatial dimensions. First\, for image restoration\, I will briefly introduce our proposed residual dense network. Then\, I will introduce the residual in residual (RIR) structure to train very deep super-resolution networks. Such an RIR structure could also make the network learn more high-frequency information\, being critical for high-resolution output. Attention mechanism (e.g.\, channel attention and spatial attention) is further explored to highlight the features. Second\, for image synthesis\, I will introduce multimodal style transfer via graph cuts. I visualize the deep features and find the multimodal style representation. I then formulate the style matching problem as an energy minimization one\, which could be solved via graph cuts. As a result\, the transferred features contain spatially semantic information\, providing more visually pleasing stylized results. Besides\, we investigate image synthesis about texture hallucination with large scaling factors. We propose an efficient high-resolution hallucination network for very large scaling factors. URL:https://coe.northeastern.edu/event/ece-phd-dissertation-defense-yulun-zhang/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210802T140000 DTEND;TZID=America/New_York:20210802T160000 DTSTAMP:20260405T044543 CREATED:20210719T153457Z LAST-MODIFIED:20210719T153457Z UID:26667-1627912800-1627920000@coe.northeastern.edu SUMMARY:Creative Expression Workshops Series: The Power of 'Yes\, and...' DESCRIPTION:MONDAY\, AUGUST 2\, 2021\n2:00 – 4:00pm\nVenue: Boston Campus\, details to follow soon\nSign up via this FORM. \nNU College of Engineering and the Department of Theatre (CAMD) are excited to host in-person creative expression workshops that help foster confidence building\, reflexivity\, collaboration and more. \nTheatre-based improvisation provides a playful environment in which to discover\, to understand and to maximize the ways in which we interact\, communicate and collaborate with others. Above all\, Improvisation helps us embrace failure as the only possible way towards real success.\n​\nParticipants will be presented with a variety of exercises that explore community and team building\, spatial awareness\, mental agility\, status\, adaptability\, risk taking\, intuition\, physical presence and relaxation. \nThe ultimate goal is for participants to experience more confidence in their ability to command the attention of an audience\, large or small\, and to be able to deepen their ability to collaborate effectively. \nAfter participating in the series\, team members may be able to: \n· Recognize and quickly adapt how they present themselves to others;\n· Read situations accurately\, practicing critical observation skills;\n· React to unexpected situations with confidence and agility;\n· Listen more deeply to others;\n· Find creative resolutions to improvised conflicts. \nINSTRUCTOR: Jesse Hinson\, Associate Teaching Professor of Theatre URL:https://coe.northeastern.edu/event/creative-expression-workshops-series-the-power-of-yes-and/ ORGANIZER;CN="Graduate School of Engineering":MAILTO:coe-gradadmissions@northeastern.edu END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210803T140000 DTEND;TZID=America/New_York:20210803T160000 DTSTAMP:20260405T044543 CREATED:20210719T153542Z LAST-MODIFIED:20210719T153542Z UID:26670-1627999200-1628006400@coe.northeastern.edu SUMMARY:Creative Expression Workshop Series: The Eloquent Bilingual Speaker DESCRIPTION:TUESDAY\, AUGUST 3\, 2021\n2:00 – 4:00pm\nVenue: Boston Campus\, details to follow soon\nSign up via this FORM. \nNU College of Engineering and the Department of Theatre (CAMD) are excited to host in-person creative expression workshops that help foster confidence building\, reflexivity\, collaboration and more. \nThis workshop is designed by and for non-native speakers of English to improve our eloquence in personal and professional interactions. Participants will learn how to free the habitual tensions\, holding patterns and inefficient uses that block the clear communication of thoughts and ideas. The playful yet demanding exercises are designed to help enhance the quality of the spoken voice\, as well as the clarity and resolve with which we express ourselves. The basic progression of exercises include: \n· Discover the skeleton & spine;\n· Stimulate breath;\n· Awaken and encourage resonance;\n· Invigorate articulation;\n· Learning the International Phonetic Alphabet as a tool to recognize clear English speech sounds and to swiftly adjust pronunciation;\nAfter participating in the series\, team members may be able to:\n· Practice relaxation\, resonance and expressiveness in the use of their voice;\n· Experience more confidence in their ability to command the attention of an audience. \nINSTRUCTOR: Antonio Ocampo-Guzman\, Associate Professor & Chair of the Department of Theatre URL:https://coe.northeastern.edu/event/creative-expression-workshop-series-the-eloquent-bilingual-speaker/ ORGANIZER;CN="Graduate School of Engineering":MAILTO:coe-gradadmissions@northeastern.edu END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210804T100000 DTEND;TZID=America/New_York:20210804T110000 DTSTAMP:20260405T044543 CREATED:20210727T185426Z LAST-MODIFIED:20210727T185426Z UID:26745-1628071200-1628074800@coe.northeastern.edu SUMMARY:ECE PhD Dissertation Defense: Amirreza Farnoosh DESCRIPTION:PhD Dissertation Defense: Unsupervised Learning of Low-Dimensional Dynamical Representations from Spatiotemporal Data \nAmirreza Farnoosh \nLocation: Zoom Link \nAbstract: Ever-improving sensing technologies offer a fast and accurate collection of large-scale spatiotemporal data\, recorded from multimodal sensors of heterogeneous natures\, in various application domains\, ranging from medicine and biology to robotics and traffic control. In this dissertation\, we propose frameworks for learning the underlying representation of these data in an unsupervised manner\, tailored towards several emerging applications\, namely indoor navigation and mapping\, neuroscience hypothesis testing\, time series forecasting\, 3D motion segmentation\, and human action recognition.\nAs such\, (1) we developed an unsupervised framework for real-time depth and view-angle estimation from an inertially augmented video recorded from an indoor scene by employing geometric-based machine learning and deep learning models. (2) We introduced a hierarchical deep generative factor analysis framework for temporal modeling of neuroimaging datasets. Our model approximates high dimensional data by a product between time-dependent weights and spatially-dependent factors which are in turn represented in terms of lower dimensional latents. This framework can be extended to perform clustering in the low dimensional temporal latent or perform factor analysis in the presence of a control signal. (3) We developed a deep switching dynamical system for dynamical modeling of multidimensional time-series data. Specifically\, we employ a deep vector auto-regressive latent model switched by a chain of discrete latents to capture higher-order multimodal latent dependencies. This results in a flexible model that (i) provides a collection of potentially interpretable states abstracted from the process dynamics\, and (ii) performs short- and long-term vector time series prediction in a complex multi-relational setting. (4) We developed a dynamical deep generative latent model for segmentation of 3D pose data over time that parses the meaningful intrinsic states in the dynamics of these data and enables a low-level dynamical generation and segmentation of skeletal movements. Our model encodes highly correlated skeletal data into a set of few spatial basis of switching temporal processes in a low-dimensional latent framework. We extended this model for human action recognition by decoding from these low-dimensional latents to the motion data and their associated action labels. URL:https://coe.northeastern.edu/event/ece-phd-dissertation-defense-amirreza-farnoosh/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210804T100000 DTEND;TZID=America/New_York:20210804T110000 DTSTAMP:20260405T044543 CREATED:20210729T142123Z LAST-MODIFIED:20210729T142123Z UID:26759-1628071200-1628074800@coe.northeastern.edu SUMMARY:ECE MS Thesis Defense: Owen McElhinney DESCRIPTION:MS Thesis Defense: On the Application of Spline Functions to Problems in Hyperspectral Imaging \nOwen McElhinney \nLocation: Zoom Link \nAbstract: Hyperspectral Imaging (HSI) is a rapidly growing topic in the field of remote sensing. Hyperspectral cameras trade off a reduction in the spatial resolution of modern imaging for a higher spectral resolution. This allows for the detection of surface materials using the principles of spectroscopy.\nThis work will investigate the application of a class of functions called splines to three different problems in the field of HSI. Splines are a special class of data-fitting functions that guarantee continuity. Common data-fitting techniques like polynomial and piecewise-polynomial fitting are unable to match the complexity of HSI data. Splines provide a robust fitting procedure that matches the physical reality of material spectra. They can additionally be used to smooth data\, calculate derivatives\, interpolate between points\, and more.\nThe first problem will look at the smoothing of noisy data for detecting small materials. When objects are smaller than the pixel\, the observed spectrum will mix the target with background materials. The problem of unmixing removes the influence of these background materials from observed data. If the object is too small\, the estimates from unmixing will be dominated by error. In this scenario\, splines will be used to smooth out these random variations.\nThe second problem will use splines to introduce a new solution to the problem of Temperature Emissivity Separation (TES). The physical quantity captured by the camera is radiance. For the detection of materials\, ground reflectance or emissivity are desired. TES is the process by which ground radiance is converted to material emissivity. Splines will be used to replace estimated roughness in this problem with an analytical solution.\nThe third and final application looks at using splines to detect gases without relying on image statistics. Gas features are sharp and only impact a narrow window of the spectrum. This application attempted to use splines to detect these sharp features by looking at the difference between the collected data and an interpolation across the feature.\nThe first two applications yielded interesting and useful results. The third application yielded some interesting conclusions about the general problem and improved methods for using splines in this space. URL:https://coe.northeastern.edu/event/ece-ms-thesis-defense-owen-mcelhinney/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210804T130000 DTEND;TZID=America/New_York:20210804T140000 DTSTAMP:20260405T044543 CREATED:20210727T185554Z LAST-MODIFIED:20210727T185554Z UID:26747-1628082000-1628085600@coe.northeastern.edu SUMMARY:ECE MS Thesis Defense: Hooman Barati Sedeh DESCRIPTION:MS Thesis Defense: Space-Time Graphene Metasurfaces \nHooman Barati Sedeh \nLocation: Zoom Link \nAbstract: The unprecedented growth of the data exchanged between wireless devices and the rapid emergence of high-quality wireless services have raised the demand for communication bandwidth and data transmission rates. This has motivated the migration of wireless networks toward the utilization of carrier waves with higher frequencies beyond the millimeter-wave band. Terahertz (THz) band is envisioned as one of the enabling technologies for future generations of wireless communication mobile networks (such as 6G) to address the needs of high-speed and bandwidth-intensive applications. THz communications are expected to provide broadband services to several wireless devices in the internet of things applications. The recent migration from internet-of-things to the internet of nano-things imposes certain constraints in terms of size\, weight\, and power (SWaP) on the THz antennas responsible for communications\, calling for the development of smart antennas with adaptive response capable of establishing multiple active data links through multi-beam scanning in a multiple-input\, multiple-output (MIMO) network while meeting the demands on the capacity and SWaP. Moreover\, provisioning a reliable communication channel that ensures the security of its users’ information remains vitally essential for the next generation of communication networks.\nMetasurfaces\, consisting of subwavelength elements\, are poised to enable improved free-space optical communications with low SWaP thanks to their small form factor and capability to provide unprecedented control over the wavefront of electromagnetic waves at the subwavelength scale. The recent investigations of active metasurfaces have aimed toward overcoming the fixed response of conventional metasurfaces and developing smart antenna systems with adaptive beamforming capabilities that can point the beam toward the desired users in real-time through pixelated control over the phase of the scattered wave. Moreover\, the adaptive communication by such quasi-static tunable metasurfaces can be secured by encrypting the transmitted data via holography to impose restrictions on the data access from an adversary. Despite the fruitful progress in this area\, quasi-static active metasurface face several challenges to meet the high demands on the capacity of communication due to their reliance on resonant phase shift accumulations which limit the operation bandwidth and hinders the scalability in terms of the number of channels in the account of non-trivial coupling effects between resonant unit cells. Furthermore\, these metasurfaces cannot be used for covert communication as they do not allow for engineering the spectral content of scattered light.\nThis thesis explores the roles of space and time in active metasurfaces for establishing adaptive and secure multichannel communication at low-THz frequency regime. As the primary goal of this work is twofold\, we will tackle each problem separately. At first\, we propose a technique for adaptive multichannel communication through simultaneous and independent multifrequency multibeam scanning via a single time-modulated metasurface consisting of graphene micro-patch antennas whose Fermi energy levels are modulated by radio-frequency biasing signals. To this aim\, we divide the metasurface aperture into interleaved orthogonally modulated sub-array antennas with distinct modulation frequencies\, rendering a shared aperture in space-time. The higher-order frequency harmonics generated by the sub-arrays in such a space-time shared-aperture metasurface are mutually orthogonal in the sense that they do not yield an observable interference pattern and can be separated by spectral filtering. A distinct constant progressive modulation phase delay is then adopted in each sub-array to independently scan its corresponding higher-order frequency harmonics via dispersionless modulation-induced phase gradient with minimal sidelobe level and full angle-of-view over a wide bandwidth. In the second part of this work\, we will propose another technique for establishing active secure communication links over single and multiple orthogonal frequency channels via a metasurface that consists of graphene micro-ribbons. To this aim\, the Fermi energy level of each graphene micro-ribbons is modulated via pseudo-random radio-frequency biasing signals whose DC offsets are adjusted to tilt the reflected beam toward the predefined direction by imposing a spatial phase gradient profile across the surface\, while their waveforms are engineered to expand the incident wave spectrum into a noise-like spectrum with a near-zero power spectral density via random modulation of the reflection phase of each element with respect to its offset phase. This permits for addressing a legitimate mobile user in real-time who can retrieve the incident signal via synchronous demodulation with the pseudo-random key of the metasurface while camouflaging the signal from the adversary by lowering the probability of detection and spectral encryption. The approach is then extended to enable multi-channel secure communication by dividing the metasurface into interleaved sub-arrays modulated with orthogonal pseudo-random keys\, which provides simultaneous and independent control over multiple beams with non-overlapping spread spectra which can be retrieved by independent legitimate users while rejecting unwarranted access by eavesdroppers as well as other users. URL:https://coe.northeastern.edu/event/ece-ms-thesis-defense-hooman-barati-sedeh/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210806T140000 DTEND;TZID=America/New_York:20210806T150000 DTSTAMP:20260405T044543 CREATED:20210730T144341Z LAST-MODIFIED:20210730T144341Z UID:26772-1628258400-1628262000@coe.northeastern.edu SUMMARY:ECE PhD Dissertation Defense: Mohammadreza Sharif DESCRIPTION:PhD Dissertation Defense: Human-in-the-loop Prosthetic Robot Hand Control through Contextual Adaptation \nMohammadreza Sharif \nLocation: ISEC136 or Zoom Link \nAbstract: Despite fifty years of research on prosthetic robot hands\, this technology is yet to be fully acknowledged by amputees as well as manufacturers\, due to lack of robustness and intuitive control. Our goal is to enhance the control robustness and intuitiveness through integrating the context\, i.e. knowledge of environment and task\, with human bio-signals\, e.g. hand trajectory. Although this solution has already been studied in the literature\, no unified framework is proposed for multi-modal information fusion. This research is aimed at introducing a novel framework for human-in-the-loop prosthetic robot hand control. We propose our solution in two parts\, (1) grasp inference and (2) end-to-end actuator control. For (1)\, we propose a model-based and a model-free grasp inference framework. Our model-based method is based on particle filters method. With knowledge of context hard-coded into the solution per se\, our particle-filter-based framework can incorporate any input signal using a proper weight function. In our model-free method we use hidden Markov mode to learn the grasp-inference task directly from human hand transport trajectories. For (2)\, we propose a reinforcement learning (RL) framework which learns to control robot actuator directly from the context with less information hard-coded into the solution. We leverage imitation learning (IL) besides RL to overcome challenging exploration in the problem. To provide invariance to the human hand transport trajectories\, we first provide a solution based on synthesized trajectories based on a human motion model. Later\, we adopt an over-sampling technique for real human hand transport trajectories\, to serve as a means of data augmentation. This research provides a step forward in more rigorous frameworks for multi-modal information fusion for prosthetic robot hand control and grasp inference through model- /data-based methods. \n  URL:https://coe.northeastern.edu/event/ece-phd-dissertation-defense-mohammadreza-sharif/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210810T100000 DTEND;TZID=America/New_York:20210810T110000 DTSTAMP:20260405T044543 CREATED:20210727T152945Z LAST-MODIFIED:20210727T152945Z UID:26733-1628589600-1628593200@coe.northeastern.edu SUMMARY:ECE PhD Dissertation Defense: Pu Zhao DESCRIPTION:PhD Dissertation Defense: Towards Robust Image Classification with Deep learning and Real-Time DNN Inference on Mobile \nPu Zhao \nLocation: Zoom Link \nAbstract:  As the rapidly increasing popularity of deep learning\, deep neural networks (DNN) have become the fundamental and essential building blocks in various applications such as image classification and object detection. However\, there are two main issues which potentially limit the wide application of DNNs: 1) the robustness of DNN models raises security concerns\, and 2) the large computation and storage requirements of DNN models lead to difficulties for its wide deployment on popular yet resource-constrained devices such as mobile phones.\nTo investigate the DNN robustness\, we explore the DNN attack\, robustness evaluation and defense. More specifically\, for DNN attack\, we achieve various attack goals (e.g. adversarial examples and fault sneaking attacks) with different algorithms (e.g. alternating direction method of multipliers (ADMM) and natural gradient descent (NGD) attacks) under various conditions (white-box and black-box attacks). For robustness evaluation\, we propose a fast evaluation method to obtain the model perturbation bound such that any model perturbation within the bound does not alter the model classification outputs or incur model mis-behaviors. For the DNN defense\, we investigate the defense performance with model connection techniques and successfully mitigate the fault sneaking and backdoor attacks. With a deeper understanding of the DNN robustness\, we further explore the deployment problem of DNN models on edge devices with limited resources.\nTo satisfy the storage and computation limitation on edge devices\, we adopt model pruning to remove the redundancy in models\, thus reducing the storage and computation during inference. Besides\, as some applications have real-time requirements with high inference speed sensitivities such as object detection on autonomous cars\, we further try to implement real-time DNN inference for various DNN applications on mobile devices with pruning and compiler optimization. To summary\, we mainly investigate the DNN robustness and implement real-time DNN inference on the mobile. URL:https://coe.northeastern.edu/event/ece-phd-dissertation-defense-pu-zhao/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210811T090000 DTEND;TZID=America/New_York:20210811T100000 DTSTAMP:20260405T044543 CREATED:20210804T174651Z LAST-MODIFIED:20210804T174651Z UID:26855-1628672400-1628676000@coe.northeastern.edu SUMMARY:Virtual Webinar with Northeastern University and University of Southern California DESCRIPTION:Topic: Engineering Studies in the United States. – Explore the newly emerging fields \nThis session will be jointly presented by EducationUSA Kolkata and two private research which are pioneer in the fields of Engineering and Applied Sciences and deal with experimental learning and focuses on newly emerging fields. This is a very pertinent session in the present context and suitable to all graduate applicants in Engineering for pursuing MS/PhD degrees\n(Note: presenters details may be added later)\nAudience: Prospective graduate students\, and parents URL:https://coe.northeastern.edu/event/virtual-webinar-with-northeastern-university-and-university-of-southern-california/ ORGANIZER;CN="Graduate School of Engineering":MAILTO:coe-gradadmissions@northeastern.edu END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210812T113000 DTEND;TZID=America/New_York:20210812T123000 DTSTAMP:20260405T044543 CREATED:20210809T133706Z LAST-MODIFIED:20210810T145007Z UID:26900-1628767800-1628771400@coe.northeastern.edu SUMMARY:ECE Teaching Presentation: Mohammad Fanaei DESCRIPTION:Title: Introduction to Python Programming with Applications in Computational Problem Solving. \nMohammad Fanaei \nLocation: Zoom Link \nAbstract: Python is a high-level\, interpreted programming language\, which supports multiple programming paradigms\, including functional and object-oriented programming. In this introductory learning conversation\, we will introduce the conditional execution of code\, loops\, and function definitions in Python. We will then apply the newly learned concepts to implement several numerical analysis methods and a Monte-Carlo simulation. The lecture will involve peer learning and assessment and assumes no background knowledge of Python programming. \nBio: Dr. Mohammad Fanaei received his Ph.D. degree in Electrical Engineering from West Virginia University\, Morgantown\, WV\, in 2016\, and his M.Sc. and B.Sc. degrees\, both in Electrical Engineering\, from Isfahan University of Technology\, Iran\, in 2008 and 2005\, respectively. Over the last six years\, Dr. Fanaei has worked at three different universities\, as an assistant professor of Electrical and Robotics & Mechatronic Systems Engineering at the University of Detroit Mercy (from 2016 to 2017 and from 2018 to present)\, as an assistant professor of Electrical Engineering at Bucknell University (from 2017 to 2018) and in the Iron Range Engineering Program in the Department of Integrated Engineering at Minnesota State University Mankato (from 2015 to 2016). Dr. Fanaei’s research interests are in the broad areas of the design\, analysis\, and evaluation of machine learning and deep learning technologies enabling connected\, automated\, and autonomous driving systems\, as well as the applications of stochastic signal processing in wireless communication systems and sensor networks. His teaching interests include embedded systems\, digital design\, wireless networks\, cryptology and network security\, communication systems\, stochastic signal processing\, and digital signal processing. URL:https://coe.northeastern.edu/event/ece-teaching-presentation-mohammad-fanaei/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210813T130000 DTEND;TZID=America/New_York:20210813T140000 DTSTAMP:20260405T044543 CREATED:20210812T182126Z LAST-MODIFIED:20210812T182126Z UID:26988-1628859600-1628863200@coe.northeastern.edu SUMMARY:ECE MS Thesis Defense: Rahul Bathini DESCRIPTION:MS Thesis Defense: Distributed Containerized Wireless Systems \nRahul Bathini \nLocation: Zoom Link \nAbstract: Future wireless communication paradigms that will form the basis of 5G and beyond architectures will rely on the availability of network infrastructure as a service. In this approach\, the same radio and compute resources are partitioned to serve many users\, each of which may prioritize different performance metrics. Thus\, with the diversity of wireless services and applications\, the current ”one size fits all” network architecture is no longer an option. Indeed\, virtualization incorporates flexibility into the network architecture design to help meet the diverse application/user needs.\nIn this thesis we consider a shared compute resource that must support a number of wireless configuration options. We study the effects of CPU allocation alongside baseband (PHY Layer) configurations such as transmitter gain and Modulation and Coding Schemes (MCS)\, related to various performance metrics of containerized wireless communications systems. We analyze these results and quantify the trends to gain a better understanding of these multiple\, interconnected effects. Finally we propose a controller to provide a user with required QoS from pre-defined Service Set identifiers (SSIDs) given the limited availability of CPU resources. We implement this controller system using open-source baseband software and USRP N310 platforms provided in the COSMOS testbed URL:https://coe.northeastern.edu/event/ece-ms-thesis-defense-rahul-bathini/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210813T130000 DTEND;TZID=America/New_York:20210813T140000 DTSTAMP:20260405T044543 CREATED:20210812T182754Z LAST-MODIFIED:20210812T182754Z UID:26990-1628859600-1628863200@coe.northeastern.edu SUMMARY:ECE MS Thesis Defense: Hafiyya Malik DESCRIPTION:MS Thesis Defense: Studies for Improving Multi-channel Confocal Fluorescence Imagining in a Multi-modal Microscope \nHafiyya Malik \nLocation: Zoom Link \nMeeting ID: 988 8423 1362 Passcode: 399185 \nAbstract: The goal of this engineering thesis was to implement confocal fluorescence microscopy in an upgraded legacy electro-optical microscopy system for characterization of the viability of cells in biofilms. This application necessitated a 2-channel fluorescence measurement with the possible addition of confocal reflectance for context. Two major areas were addressed. First was the potential for using a silicon photomultiplier (SiPM) detector to replace the usual vacuum photomultiplier employed in confocal fluorescence microscope. A SiPM development board was purchased and tested to determine its performance at different light levels and in the presence of background light. The SiPM has the potential to be a more robust and reliable detector\, with the one disadvantage of a smaller area than some vacuum photomultipliers. The second area was the alignment of a long optical path that must include optics for complementary modes of imaging and allow for automated measurement across two spectral channels without loss of alignment. Alignment procedures were developed to simplify the process of alignment and a sliding stage was used to maintain alignment of two dichroic filters when changing channels. Based on this work\, multi-channel confocal fluorescence imaging in conjunction with confocal reflectance and bright-field microscope will be possible. URL:https://coe.northeastern.edu/event/ece-ms-thesis-defense-hafiyya-malik/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210823T120000 DTEND;TZID=America/New_York:20210823T123000 DTSTAMP:20260405T044543 CREATED:20210803T155117Z LAST-MODIFIED:20210803T155117Z UID:26793-1629720000-1629721800@coe.northeastern.edu SUMMARY:How can I avoid predatory publishers? A Bite-Sized Webinar DESCRIPTION:Have you ever received an email from a journal asking you to submit your work? How can you tell whether the journal is predatory or legitimate? In this 20-minute workshop\, you will learn how to recognize signs of deceptive publishing practices by examining solicitation emails and journal websites. \nClick this link to register! \nPresented by Philip Espinola Coombs and Luesoni Kuck as part of Snell Library’s popular Bite-Sized Webinars series: \nCurious about a topic\, but simply don’t have the time to attend a full length webinar? Our Bite-Sized Webinars are 20 minute webinars designed to give you a short introduction or overview of a topic. We have presenters from a variety of library departments that include research and instruction\, data management\, data scholarship\, and data visualization. Each of the webinars will be recorded\, captioned and sent to registrants. \nYou can view the list of upcoming Bite-Sized Webinars below or see the full listing here. URL:https://coe.northeastern.edu/event/how-can-i-avoid-predatory-publishers-a-bite-sized-webinar/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210825T103000 DTEND;TZID=America/New_York:20210825T113000 DTSTAMP:20260405T044543 CREATED:20210817T200348Z LAST-MODIFIED:20210823T134620Z UID:27018-1629887400-1629891000@coe.northeastern.edu SUMMARY:ECE PhD Dissertation Defense: Apoorve Mohan DESCRIPTION:PhD Dissertation Defense: Rethinking the Choice between Static and Dynamic Provisioning for Centralized Bare-Metal Deployments \nApoorve Mohan \nLocation: Zoom Link \nAbstract: Technological inertia leads many organizations to continue to employ static provisioning strategies for bare-metal deployments. This results in architectural and runtime inefficiencies. However\, most performance and security-sensitive organizations currently employ static provisioning strategies to run and manage their workloads on physical servers (also known as bare-metal servers). This thesis demonstrates how recent technological advances enable dynamic provisioning strategies to improve aggregate bare-metal resource efficiency in centralized bare-metal deployments. Conceptually\, this dissertation has four parts. First\, it introduces a new system architecture for dynamic bare-metal provisioning. The proposed architecture reduces overhead and operational complexity and improves fault tolerance and performance. To achieve these improvements\, it decouples the provisioned state from the bare-metal servers. Second\, the thesis identifies the performance and operational issues due to intrusive software introspection strategies employed in existing bare-metal deployments. We present a dynamic bare-metal provisioning-based system to enable non-intrusive software introspection of bare-metal deployments to mitigate these issues. Many organizations have realized the cost benefits of consolidating their computing infrastructure over managing multiple\, relatively smaller compute facilities. \nOver the past decade\, virtual infrastructure solutions have become the obvious choice in consolidated (i.e.\, single-tenant managed or centralized) deployments for many organizations due to the scalability\, availability\, and cost benefits it offers. However\, most performance and security-sensitive organizations such as medical companies and hospitals\, financial institutions\, federal agencies run their workloads directly on physical (i.e.\, bare-metal) infrastructure. They are unwilling to tolerate the performance unpredictability and security risks due to co-location and performance overhead or vulnerabilities due to a large code base of the complex virtualization stack. In addition\, even if an organization uses virtual infrastructure\, bare-metal infrastructure is used to set up virtualization software stack and when their workloads require direct and exclusive access to hardware components (e.g.\, InfiniBand\, RAID\, FPGAs\, GPUs) that are difficult to virtualize. Such organizations invest enormous sums of money to buy or rent bare-metal servers and set up and manage bare-metal clusters. Thus\, it is imperative that these organizations efficiently operate and utilize the bare-metal clusters they set up to maximize their investment returns. However\, despite the technological advances over the past decade\, organizations continually employ static provisioning strategies in bare-metal deployments that contribute to poor aggregate bare-metal resource efficiency. Thesis Statement: This thesis demonstrates how dynamic provisioning can mitigate observed inefficiencies in centralized bare-metal deployments. The proposed dynamic provisioning strategies leverages existing storage disaggregation and fault-tolerance technologies to improve aggregate bare-metal resource efficiency. By applying it to four real-world scenarios\, this thesis demonstrates the effectiveness of dynamic provisioning. URL:https://coe.northeastern.edu/event/ece-phd-dissertation-defense-apoorve-mohan/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210825T120000 DTEND;TZID=America/New_York:20210825T123000 DTSTAMP:20260405T044543 CREATED:20210803T155617Z LAST-MODIFIED:20210803T155617Z UID:26817-1629892800-1629894600@coe.northeastern.edu SUMMARY:How do I get started with ArcGIS at Northeastern? A Bite-Sized Webinar DESCRIPTION:In this session\, I will introduce ArcGIS web maps and applications which are available through the ESRI license to Northeastern Community. Join me to have a glance at ArcGIS webmaps\, storymaps\, filed data collector\, dashboard and business analyst. \nClick this link to register! \nPresented by Geospatial & GIS Specialist\, Bahare Sanaie-Movahed\, as part of Snell Library’s popular Bite-Sized Webinars series: \nCurious about a topic\, but simply don’t have the time to attend a full length webinar? Our Bite-Sized Webinars are 20 minute webinars designed to give you a short introduction or overview of a topic. We have presenters from a variety of library departments that include research and instruction\, data management\, data scholarship\, and data visualization. Each of the webinars will be recorded\, captioned and sent to registrants. \nYou can view the list of upcoming Bite-Sized Webinars below or see the full listing here. URL:https://coe.northeastern.edu/event/how-do-i-get-started-with-arcgis-at-northeastern-a-bite-sized-webinar/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210826T120000 DTEND;TZID=America/New_York:20210826T123000 DTSTAMP:20260405T044543 CREATED:20210803T155647Z LAST-MODIFIED:20210803T155647Z UID:26827-1629979200-1629981000@coe.northeastern.edu SUMMARY:How do I get free access to the standards I need? A Bite-Sized Webinar DESCRIPTION:If you’re designing or testing a new product or process\, you’ll probably need to use standards. But standards can be expensive\, and tough to find. This workshop will cover some tips for getting the standards you need\, including how to find them\, how you can access (some) standards for free through the library\, and what to do when the standard you need is behind a paywall. \nClick this link to register! \nPresented by Jodi Bolognese\, Engineering Librarian as part of Snell Library’s popular Bite-Sized Webinars series: \nCurious about a topic\, but simply don’t have the time to attend a full length webinar? Our Bite-Sized Webinars are 20 minute webinars designed to give you a short introduction or overview of a topic. We have presenters from a variety of library departments that include research and instruction\, data management\, data scholarship\, and data visualization. Each of the webinars will be recorded\, captioned and sent to registrants. \nYou can view the list of upcoming Bite-Sized Webinars below or see the full listing here. URL:https://coe.northeastern.edu/event/how-do-i-get-free-access-to-the-standards-i-need-a-bite-sized-webinar/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210827T120000 DTEND;TZID=America/New_York:20210827T123000 DTSTAMP:20260405T044543 CREATED:20210803T155720Z LAST-MODIFIED:20210803T155720Z UID:26831-1630065600-1630067400@coe.northeastern.edu SUMMARY:What are persistent identifiers and why do they matter? A Bite-Sized Webinar DESCRIPTION:Persistent identifiers\, or PIDs\, are unique codes used to unambiguously identify people\, places\, and things. You should care about them because when you use PIDs\, you can get credit for your hard-fought research outputs from papers to data and more. In this session\, we’ll give a quick overview of some of the more common PIDs in academia like ORCIDs\, DOIs\, RORs and RAIDs (oh my). Join us and become a PID Person! \nClick this link to register! \nThis webinar is part of Snell Library’s popular Bite-Sized Webinars series: \nCurious about a topic\, but simply don’t have the time to attend a full length webinar? Our Bite-Sized Webinars are 20 minute webinars designed to give you a short introduction or overview of a topic. We have presenters from a variety of library departments that include research and instruction\, data management\, data scholarship\, and data visualization. Each of the webinars will be recorded\, captioned and sent to registrants. \nYou can view the list of upcoming Bite-Sized Webinars below or see the full listing here. URL:https://coe.northeastern.edu/event/what-are-persistent-identifiers-and-why-do-they-matter-a-bite-sized-webinar/ END:VEVENT BEGIN:VEVENT DTSTART;TZID=America/New_York:20210830T093000 DTEND;TZID=America/New_York:20210830T103000 DTSTAMP:20260405T044543 CREATED:20210819T175252Z LAST-MODIFIED:20210819T175252Z UID:27047-1630315800-1630319400@coe.northeastern.edu SUMMARY:ECE PhD Proposal Review: Keng Chen DESCRIPTION:PhD Proposal Review: Design of Accurate and Responsive Power Management Integrated Circuits for Microprocessor Systems \nKeng Chen \nLocation: Zoom Link \nAbstract: As technology improves\, the processors used in data centers are becoming increasingly powerful. Since the number of complementary metal-oxide semiconductor (CMOS) transistors integrated into these processors continues to rise\, it becomes more challenging to design the power management integrated circuits to accurately regulate the supply voltages and ensure fast operational speeds for the processors. Furthermore\, with multi-core technology being extensively used in processor design\, there is more than just one voltage rail per chip that needs to be precisely regulated. In this research\, circuit design methods will be developed to improve the regulation accuracy\, both of the output voltage and converter switching frequency\, which are proposed for an integrated buck regulator designed for point of load (POL) applications. In order to ensure both accuracy and fast speed of operation\, a constant-on-time (COT) architecture was selected for this integrated buck regulator design approach. To provide accurate output voltage regulation\, the on-chip feedback sensing network and the bandgap reference circuit need to exhibit high accuracy. For this reason\, a highly accurate bandgap reference generation circuit with 5.8 ppm/°C – 13.5 ppm/°C over a wide operational region (-40 °C to 150 °C) has been designed. This bandgap reference circuit has a current-mode architecture and provides a 1.16V reference voltage with a 3.3V supply. A multi-section curvature compensation method is proposed to alleviate the nonlinear temperature-dependent error from the bipolar junction transistor’s base-emitter voltage. The two operational amplifiers utilized in this bandgap reference design to generate proportional-to-absolute-temperature (PTAT) and complementary-to-absolute-temperature (CTAT) current sources share one auxiliary auto-zero amplifier to ensure low input-referred offset voltage. Within many voltage regulators\, the feedback sensing network consists of multiple operational amplifiers\, and a major error source is the impact of the input-referred offset voltages of these amplifiers. \nThis research introduces the utilization of two different input-referred offset voltage correction methods for multiple amplifiers. The multi-amplifier system under investigation is used for feedback sensing during voltage regulation. It contains an instrumentation amplifier consisting of three folded cascode stages\, and an additional amplifier configured as a unity-gain buffer for a reference voltage. The first method in this work alleviates voltage offsets in a 4-amplifier system based on a shared auxiliary amplifier correction circuit that switches between different target amplifiers. The second method applies a chopping-based auto-zero procedure to cancel the input-referred offset voltage of the same system. Since chopping causes voltage ripples\, a correction circuit with a successive approximation register (SAR) analog-to-digital converter is used to reduce the output ripples. Both proposed methods can achieve less than 1mV feedback sensing error in voltage regulator applications.\nFor the constant-on-time buck regulator itself\, a new frequency locking loop to regulate the on-time pulse is also proposed in this work. The system shows less than 1% frequency shift over a wide programmable operational frequency range (400 KHz to 2 MHz). This frequency accuracy will further benefit the constant-on-time circuit to meet electromagnetic interference requirements without harming the fast-transient performance. URL:https://coe.northeastern.edu/event/ece-phd-proposal-review-keng-chen/ END:VEVENT BEGIN:VEVENT DTSTART;VALUE=DATE:20210831 DTEND;VALUE=DATE:20210901 DTSTAMP:20260405T044543 CREATED:20210819T135445Z LAST-MODIFIED:20210819T135445Z UID:27040-1630368000-1630454399@coe.northeastern.edu SUMMARY:Northeastern University Graduate Expo DESCRIPTION:This day-long virtual experience will allow you to connect with staff\, students\, and admissions representatives to learn more about the university and how we can help your academic journey and career.\n\nClick here to view the agenda for the day.\n\nJoin live panels and information sessions during the event and enjoy access to on-demand video content whenever you’d like.\n\nRegister Today URL:https://coe.northeastern.edu/event/northeastern-university-graduate-expo/ ORGANIZER;CN="Graduate School of Engineering":MAILTO:coe-gradadmissions@northeastern.edu END:VEVENT END:VCALENDAR