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1. Near-term regional climate change in East Africa

Author

Parsons Laboratory for Environmental Science and Engineering (Massachusetts Institute of Technology), Lincoln Laboratory, Choi, Yeon-Woo, Campbell, Deborah J., Eltahir, Elfatih A.B., Parsons Laboratory for Environmental Science and Engineering (Massachusetts Institute of Technology), Lincoln Laboratory, Choi, Yeon-Woo, Campbell, Deborah J., and Eltahir, Elfatih A.B.

Abstract

In the coming few decades, projected increases in global temperature and humidity are generally expected to exacerbate human exposure to climate extremes (e.g., humid-heat and rainfall extremes). Despite the growing risk of humid-heat stress (measured by wet-bulb temperature), it has received less attention in East Africa, where arid and semi-arid climatic conditions prevail. Moreover, no consensus has yet been reached across models regarding future changes in rainfall over this region. Here, we screen Global Climate Models (GCMs) from CMIP5 and CMIP6 and use, for boundary conditions, simulations from only those GCMs that simulate successfully recent climatic trends. Based on these GCMs and Regional Climate Model (RCM) simulations, we project that annual mean temperature is likely to rise by 2 ℃ toward midcentury (2021–2050) ​at a faster rate than the global average (about 1.5 ℃), under the RCP8.5 and SSP5-8.5 scenarios, associated with more frequent and severe climate extremes. In particular, low-lying regions in East Africa will be vulnerable to severe heat stress, with an extreme wet-bulb temperature approaching or exceeding the US National Weather Service’s extreme danger threshold of 31 ℃. On the other hand, population centers in the highlands of Ethiopia will receive significantly more precipitation during the autumn season and will see more extreme rainfall events, with implications for flooding and agriculture. The robustness of these results across all GCM and RCM simulations, and for both of CMIP5 and CMIP6 frameworks (CMIP: Coupled Model Inter-comparison Project) supports the reliability of these future projections. Our simulations of near-term climate change impacts are designed to inform the development of sound adaptation strategies for the region.

Published
2023

2. Teaching computing for complex problems in civil engineering and geosciences using big data and machine learning: synergizing four different computing paradigms and four different management domains

Author

Massachusetts Institute of Technology. Laboratory for Information and Decision Systems, Lincoln Laboratory, Babović, Zoran, Bajat, Branislav, Barac, Dusan, Bengin, Vesna, Đokić, Vladan, Đorđević, Filip, Drašković, Dražen, Filipović, Nenad, French, Stephan, Furht, Borko, Ilić, Marija, Irfanoglu, Ayhan, Kartelj, Aleksandar, Kilibarda, Milan, Klimeck, Gerhard, Massachusetts Institute of Technology. Laboratory for Information and Decision Systems, Lincoln Laboratory, Babović, Zoran, Bajat, Branislav, Barac, Dusan, Bengin, Vesna, Đokić, Vladan, Đorđević, Filip, Drašković, Dražen, Filipović, Nenad, French, Stephan, Furht, Borko, Ilić, Marija, Irfanoglu, Ayhan, Kartelj, Aleksandar, Kilibarda, Milan, and Klimeck, Gerhard

Abstract

This article describes a teaching strategy that synergizes computing and management, aimed at the running of complex projects in industry and academia, in the areas of civil engineering, physics, geosciences, and a number of other related fields. The course derived from this strategy includes four parts: (a) Computing with a selected set of modern paradigms—the stress is on Control Flow and Data Flow computing paradigms, but paradigms conditionally referred to as Energy Flow and Diffusion Flow are also covered; (b) Project management that is holistic—the stress is on the wide plethora of issues spanning from the preparation of project proposals, all the way to incorporation activities to follow after the completion of a successful project; (c) Examples from past research and development experiences—the stress is on experiences of leading experts from academia and industry; (d) Student projects that stimulate creativity—the stress is on methods that educators could use to induce and accelerate the creativity of students in general. Finally, the article ends with selected pearls of wisdom that could be treated as suggestions for further elaboration.

Published
2023

7. Multimodal Conversational Agents for People with Neurodevelopmental Disorders

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Catania, Fabio, Talkar, Tanya, Garzotto, Franca, Cowan, Benjamin, Quatieri, Thomas, Ghosh, Satrajit, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Catania, Fabio, Talkar, Tanya, Garzotto, Franca, Cowan, Benjamin, Quatieri, Thomas, and Ghosh, Satrajit

Published
2023

9. Densification of Ionic Liquid Electrospray Thrusters using Silicon-Based MEMS Fabrication

Author

Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Lincoln Laboratory, Corrado, Matthew N., Lozano, Paulo C., Parameswaran, Lalitha, Cook, Matthew, Holihan, Eric C., Mathews, Richard, Racz, Livia M., Smith, Melissa A., Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Lincoln Laboratory, Corrado, Matthew N., Lozano, Paulo C., Parameswaran, Lalitha, Cook, Matthew, Holihan, Eric C., Mathews, Richard, Racz, Livia M., and Smith, Melissa A.

Abstract

Department of Defense (DoD), National Science Foundation (NSF)

Published
2023

10. A Wide-Area Deep Ocean Floor Mapping System: Design and Sea Tests

Author

Lincoln Laboratory, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Center for Computational Science and Engineering, Ryu, Paul, Brown, David, Arsenault, Kevin, Cho, Byunggu, March, Andrew, Ali, Wael H., Charous, Aaron, Lermusiaux, Pierre F. J., Lincoln Laboratory, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Center for Computational Science and Engineering, Ryu, Paul, Brown, David, Arsenault, Kevin, Cho, Byunggu, March, Andrew, Ali, Wael H., Charous, Aaron, and Lermusiaux, Pierre F. J.

Abstract

Mapping the seafloor in the deep ocean is currently performed using sonar systems on surface vessels (low-resolution maps) or undersea vessels (high-resolution maps). Surface-based mapping can cover a much wider search area and is not burdened by the complex logistics required for deploying undersea vessels. However, practical size constraints for a towbody or hull-mounted sonar array result in limits in beamforming and imaging resolution. For cost-effective high-resolution mapping of the deep ocean floor from the surface, a mobile wide-aperture sparse array with subarrays distributed across multiple autonomous surface vessels (ASVs) has been designed. Such a system could enable a surface-based sensor to cover a wide area while achieving high-resolution bathymetry, with resolution cells on the order of 1 m2 at a 6 km depth. For coherent 3D imaging, such a system must dynamically track the precise relative position of each boat’s sonar subarray through ocean-induced motions, estimate water column and bottom reflection properties, and mitigate interference from the array sidelobes. Sea testing of this core sparse acoustic array technology has been conducted, and planning is underway for relative navigation testing with ASVs capable of hosting an acoustic subarray.

Published
2023

12. On Randomization in MTD Systems

Author

Lincoln Laboratory, Ghaderi, Majid, Jero, Samuel, Nita-Rotaru, Cristina, Safavi-Naini, Reihaneh, Lincoln Laboratory, Ghaderi, Majid, Jero, Samuel, Nita-Rotaru, Cristina, and Safavi-Naini, Reihaneh

Published
2023

15. Clover: Toward Sustainable AI with Carbon-Aware Machine Learning Inference Service

Author

Lincoln Laboratory, Li, Baolin, Samsi, Siddharth, Gadepally, Vijay, Tiwari, Devesh, Lincoln Laboratory, Li, Baolin, Samsi, Siddharth, Gadepally, Vijay, and Tiwari, Devesh

Abstract

This paper presents a solution to the challenge of mitigating carbon emissions from hosting large-scale machine learning (ML) inference services. ML inference is critical to modern technology products, but it is also a significant contributor to carbon footprint. We introduce, Clover, a carbon-friendly ML inference service runtime system that balances performance, accuracy, and carbon emissions through mixed-quality models and GPU resource partitioning. Our experimental results demonstrate that Clover is effective in substantially reducing carbon emissions while maintaining high accuracy and meeting service level agreement (SLA) targets.

Published
2023

16. Impact of WSR-88D Intra-Volume Low-Level Scans on Severe Weather Warning Performance

Author

Lincoln Laboratory, Cho, John Y. N., Kurdzo, James M., Bennett, Betty J., Weber, Mark E., Dellicarpini, Joseph W., Loconto, Andrew, Frank, Hayden, Lincoln Laboratory, Cho, John Y. N., Kurdzo, James M., Bennett, Betty J., Weber, Mark E., Dellicarpini, Joseph W., Loconto, Andrew, and Frank, Hayden

Abstract

The statistical relationship between supplemental adaptive intra-volume low-level scan (SAILS) usage on the Weather Surveillance Radar-1988 Doppler and National Weather Service severe storm warning performance during 2014–20 is analyzed. Results show statistically significant improvement in severe thunderstorm (SVR), flash flood (FF), and tornado (TOR) warning performance associated with SAILS-on versus SAILS-off. Within the three possible SAILS modes of one (SAILSx1), two (SAILSx2), and three (SAILSx3) additional base scans per volume, for SVR, SAILSx2 and SAILSx3 are associated with better warning performance compared to SAILSx1; for FF and TOR, SAILSx3 is associated with better warning performance relative to SAILSx1 and SAILSx2. Two severe storm cases (one that spawned a tornado, one that did not) are presented where SAILS usage helped forecasters make the correct TOR warning decision, lending real-life credence to the statistical results. Furthermore, a statistical analysis of automated volume scan evaluation and termination effects, parsed by SAILS usage and mode, yield a statistically significant association between volume scan update rate and SVR warning lead time., National Ocean and Atmospheric Administration (NOAA)

Published
2023

17. A Deep Learning–Based Velocity Dealiasing Algorithm Derived from the WSR-88D Open Radar Product Generator

Author

Lincoln Laboratory, Veillette, Mark S., Kurdzo, James M., Stepanian, Phillip M., McDonald, Joseph, Samsi, Siddharth, Cho, John Y. N., Lincoln Laboratory, Veillette, Mark S., Kurdzo, James M., Stepanian, Phillip M., McDonald, Joseph, Samsi, Siddharth, and Cho, John Y. N.

Abstract

Radial velocity estimates provided by Doppler weather radar are critical measurements used by operational forecasters for the detection and monitoring of life-impacting storms. The sampling methods used to produce these measurements are inherently susceptible to aliasing, which produces ambiguous velocity values in regions with high winds and needs to be corrected using a velocity dealiasing algorithm (VDA). In the United States, the Weather Surveillance Radar-1988 Doppler (WSR-88D) Open Radar Product Generator (ORPG) is a processing environment that provides a world-class VDA; however, this algorithm is complex and can be difficult to port to other radar systems outside the WSR-88D network. In this work, a deep neural network (DNN) is used to emulate the two-dimensional WSR-88D ORPG dealiasing algorithm. It is shown that a DNN, specifically a customized U-Net, is highly effective for building VDAs that are accurate, fast, and portable to multiple radar types. To train the DNN model, a large dataset is generated containing aligned samples of folded and dealiased velocity pairs. This dataset contains samples collected from WSR-88D Level-II and Level-III archives and uses the ORPG dealiasing algorithm output as a source of truth. Using this dataset, a U-Net is trained to produce the number of folds at each point of a velocity image. Several performance metrics are presented using WSR-88D data. The algorithm is also applied to other non-WSR-88D radar systems to demonstrate portability to other hardware/software interfaces. A discussion of the broad applicability of this method is presented, including how other Level-III algorithms may benefit from this approach. Significance Statement Accurate and timely estimates of wind within storms are critically important for a number of applications, including severe storm nowcasting, maritime operational planning, aviation forecasting, and public safety coordination. Velocity, Department of Defense (DoD)

Published
2023

18. Extended Polarimetric Observations of Chaff Using the WSR-88D Weather Radar Network

Author

Lincoln Laboratory, Kurdzo, James M., Bennett, Betty J., Cho, John Y. N., Donovan, Michael F., Lincoln Laboratory, Kurdzo, James M., Bennett, Betty J., Cho, John Y. N., and Donovan, Michael F.

Abstract

Military chaff is a metallic, fibrous radar countermeasure that is released by aircraft and rockets for diversion and masking of targets. It is often released across the United States for training purposes, and, due to its resonant cut lengths, is often observed on the S-band Weather Surveillance Radar – 1988 Doppler (WSR-88D) network. Efforts to identify and characterize chaff and other non-meteorological targets algorithmically require a statistical understanding of the targets. Previous studies of chaff characteristics have provided important information that has proven to be useful for algorithmic development. However, recent changes to the WSR-88D processing suite have allowed for a vastly extended range of differential reflectivity, a prime topic of previous studies on chaff using weather radar. Motivated by these changes, a new dataset of 2.8 million range gates of chaff from 267 cases across the United States is analyzed. With a better spatiotemporal representation of cases compared to previous studies, new analyses of height dependence, as well as changes in statistics by volume coverage pattern are examined, along with an investigation of the new “full” range of differential reflectivity. A discussion of how these findings are being used in WSR-88D algorithm development is presented, specifically with a focus on machine learning and separation of different target types., National Ocean and Atmospheric Administration (NOAA)

Published
2023

19. Sustainable Supercomputing for AI: GPU Power Capping at HPC Scale

Author

Lincoln Laboratory, Zhao, Dan, Samsi, Siddharth, McDonald, Joseph, Li, Baolin, Bestor, David, Jones, Michael, Tiwari, Devesh, Gadepally, Vijay, Lincoln Laboratory, Zhao, Dan, Samsi, Siddharth, McDonald, Joseph, Li, Baolin, Bestor, David, Jones, Michael, Tiwari, Devesh, and Gadepally, Vijay

Published
2023

20. Toward Sustainable HPC: Carbon Footprint Estimation and Environmental Implications of HPC Systems

Author

Lincoln Laboratory, Li, Baolin, Basu Roy, Rohan, Wang, Daniel, Samsi, Siddharth, Gadepally, Vijay, Tiwari, Devesh, Lincoln Laboratory, Li, Baolin, Basu Roy, Rohan, Wang, Daniel, Samsi, Siddharth, Gadepally, Vijay, and Tiwari, Devesh

Abstract

The rapid growth in demand for HPC systems has led to a rise in carbon footprint, which requires urgent intervention. In this work, we present a comprehensive analysis of the carbon footprint of highperformance computing (HPC) systems, considering the carbon footprint during both the hardware manufacturing and system operational stages. Our work employs HPC hardware component carbon footprint modeling, regional carbon intensity analysis, and experimental characterization of the system life cycle to highlight the importance of quantifying the carbon footprint of HPC systems.

Published
2023

21. Noninvasive Monitoring of Simulated Hemorrhage and Whole Blood Resuscitation

Author

Lincoln Laboratory, Gupta, Jay F., Arshad, Saaid H., Telfer, Brian A., Snider, Eric J., Convertino, Victor A., Lincoln Laboratory, Gupta, Jay F., Arshad, Saaid H., Telfer, Brian A., Snider, Eric J., and Convertino, Victor A.

Abstract

Hemorrhage is the leading cause of preventable death from trauma. Accurate monitoring of hemorrhage and resuscitation can significantly reduce mortality and morbidity but remains a challenge due to the low sensitivity of traditional vital signs in detecting blood loss and possible hemorrhagic shock. Vital signs are not reliable early indicators because of physiological mechanisms that compensate for blood loss and thus do not provide an accurate assessment of volume status. As an alternative, machine learning (ML) algorithms that operate on an arterial blood pressure (ABP) waveform have been shown to provide an effective early indicator. However, these ML approaches lack physiological interpretability. In this paper, we evaluate and compare the performance of ML models trained on nine ABP-derived features that provide physiological insight, using a database of 13 human subjects from a lower-body negative pressure (LBNP) model of progressive central hypovolemia and subsequent progressive restoration to normovolemia (i.e., simulated hemorrhage and whole blood resuscitation). Data were acquired at multiple repressurization rates for each subject to simulate varying resuscitation rates, resulting in 52 total LBNP collections. This work is the first to use a single ABP-based algorithm to monitor both simulated hemorrhage and resuscitation. A gradient-boosted regression tree model trained on only the half-rise to dicrotic notch (HRDN) feature achieved a root-mean-square error (RMSE) of 13%, an R2 of 0.82, and area under the receiver operating characteristic curve of 0.97 for detecting decompensation. This single-feature model’s performance compares favorably to previously reported results from more-complex black box machine learning models. This model further provides physiological insight because HRDN represents an approximate measure of the delay between the ABP ejected and reflected wave and therefore is an indication of cardiac and peripheral v

Published
2022

22. Large-Scale Magnetic Microcalorimeter Arrays for the Lynx X-Ray Microcalorimeter

Author

Lincoln Laboratory, Devasia, Archana M., Bandler, Simon R., Ryu, Kevin, Stevenson, Thomas R., Yoon, Wonsik, Lincoln Laboratory, Devasia, Archana M., Bandler, Simon R., Ryu, Kevin, Stevenson, Thomas R., and Yoon, Wonsik

Abstract

The Lynx X-ray microcalorimeter (LXM) is an imaging spectrometer consisting of an array of greater than 100,000 pixels. Magnetic microcalorimeter (MMC) technology is a leading contender for detectors for the LXM. In this work, we detail the design of a full-size LXM MMC array fabricated using superconducting, multi-layer, buried wiring, with all pixels wired out on a full-size support wafer. We adopt a scheme that facilitates mixing and matching deep UV (DUV) and i-line (365 nm) steppers to stitch the high feature resolution detector array to the large field fanout wiring. To realize the main array of the microcalorimeter, we also employ a sandwich geometry. In this type of pixel, a superconducting ground plane placed above a paramagnetic sensor forces most of the magnetic flux to remain inside the sensor. This device aims to improve the coupling of the sensor to the pick-up coil, and thus enhance the energy resolution. Additionally, we introduce the integration of superconducting flux transformers to optimize the performance of the Ultra High Resolution Array. The wiring to each pixel terminates on bump bond pads, which allow future 2D microwave SQUID-based multiplexer chips to be indium bump bonded over the buried wiring. We present fabrication results and preliminary room temperature electrical measurements.

Published
2022

23. Emerging Terahertz Integrated Systems in Silicon

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, Yi, Xiang, Wang, Cheng, Hu, Zhi, Holloway, Jack W, Khan, Muhammad Ibrahim Wasiq, Ibrahim, Mohamed I, Kim, Mina, Dogiamis, Georgios C, Perkins, Bradford, Kaynak, Mehmet, Yazicigil, Rabia Tugce, Chandrakasan, Anantha P, Han, Ruonan, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, Yi, Xiang, Wang, Cheng, Hu, Zhi, Holloway, Jack W, Khan, Muhammad Ibrahim Wasiq, Ibrahim, Mohamed I, Kim, Mina, Dogiamis, Georgios C, Perkins, Bradford, Kaynak, Mehmet, Yazicigil, Rabia Tugce, Chandrakasan, Anantha P, and Han, Ruonan

Published
2022

24. Mediated Interactions beyond the Nearest Neighbor in an Array of Superconducting Qubits

Author

Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Lincoln Laboratory, Yanay, Yariv, Braumüller, Jochen, Orlando, Terry P, Gustavsson, Simon, Tahan, Charles, Oliver, William D, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Lincoln Laboratory, Yanay, Yariv, Braumüller, Jochen, Orlando, Terry P, Gustavsson, Simon, Tahan, Charles, and Oliver, William D

Abstract

We consider mediated interactions in an array of floating transmons, where each qubit capacitor consists of two superconducting pads galvanically isolated from ground. Each such pair contributes two quantum degrees of freedom, one of which is used as a qubit, while the other remains fixed. However, these extraneous modes can generate coupling between the qubit modes that extends beyond the nearest neighbor. We present a general formalism describing the formation of this coupling and calculate it for a one-dimensional chain of transmons. We show that the strength of coupling and its range (that is, the exponential falloff) can be tuned independently via circuit design to realize a continuum from nearest-neighbor-only interactions to interactions that extend across the length of the chain. We present designs with capacitance and microwave simulations showing that various interaction configurations can be achieved in realistic circuits. Such coupling could be used in analog simulation of different quantum regimes or to increase connectivity in digital quantum systems. Thus mechanism must also be taken into account in other types of qubits with extraneous modes.

Published
2022

25. Towards the Next Generation Operational Meteorological Radar

Author

Lincoln Laboratory, Weber, Mark, Hondl, Kurt, Yussouf, Nusrat, Jung, Youngsun, Stratman, Derek, Putnam, Bryan, Wang, Xuguang, Schuur, Terry, Kuster, Charles, Wen, Yixin, Sun, Juanzhen, Keeler, Jeff, Ying, Zhuming, Cho, John, Kurdzo, James, Torres, Sebastian, Curtis, Chris, Schvartzman, David, Boettcher, Jami, Nai, Feng, Thomas, Henry, Zrnić, Dusan, Ivić, Igor, Mirković, Djordje, Fulton, Caleb, Salazar, Jorge, Zhang, Guifu, Palmer, Robert, Yeary, Mark, Cooley, Kevin, Istok, Michael, Vincent, Mark, Lincoln Laboratory, Weber, Mark, Hondl, Kurt, Yussouf, Nusrat, Jung, Youngsun, Stratman, Derek, Putnam, Bryan, Wang, Xuguang, Schuur, Terry, Kuster, Charles, Wen, Yixin, Sun, Juanzhen, Keeler, Jeff, Ying, Zhuming, Cho, John, Kurdzo, James, Torres, Sebastian, Curtis, Chris, Schvartzman, David, Boettcher, Jami, Nai, Feng, Thomas, Henry, Zrnić, Dusan, Ivić, Igor, Mirković, Djordje, Fulton, Caleb, Salazar, Jorge, Zhang, Guifu, Palmer, Robert, Yeary, Mark, Cooley, Kevin, Istok, Michael, and Vincent, Mark

Abstract

AbstractThis article summarizes research and risk reduction that will inform acquisition decisions regarding NOAA’s future national operational weather radar network. A key alternative being evaluated is polarimetric phased-array radar (PAR). Research indicates PAR can plausibly achieve fast, adaptive volumetric scanning, with associated benefits for severe-weather warning performance. We assess these benefits using storm observations and analyses, observing system simulation experiments, and real radar-data assimilation studies. Changes in the number and/or locations of radars in the future network could improve coverage at low altitude. Analysis of benefits that might be so realized indicates the possibility for additional improvement in severe-weather and flash-flood warning performance, with associated reduction in casualties. Simulations are used to evaluate techniques for rapid volumetric scanning and assess data quality characteristics of PAR. Finally, we describe progress in developing methods to compensate for polarimetric variable estimate biases introduced by electronic beam-steering. A research-to-operations (R2O) strategy for the PAR alternative for the WSR-88D replacement network is presented., National Ocean and Atmospheric Administration (NOAA)

Published
2022

26. Status update of LLAMAS: a wide field-of-view visible passband IFU for the 6.5m Magellan telescopes

Author

MIT Kavli Institute for Astrophysics and Space Research, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Lincoln Laboratory, Furész, Gábor, Simcoe, Robert A, Egan, Mark D, Malonis, Andrew, Masterson, Rebecca A, Brown, Joshua, Cappiello, Gregory, Chesbrough, Christian, Clark, Kristin, Coppeta, David, Frostig, Danielle, Gabutti, Michelle, Halverson, Samuel P, Hinrichsen, Erik, Kahn, Sabrina, Lambert, Madeline M, Lourie, Nathan P, Piotrowski, John, Semisch, Christopher, MIT Kavli Institute for Astrophysics and Space Research, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Lincoln Laboratory, Furész, Gábor, Simcoe, Robert A, Egan, Mark D, Malonis, Andrew, Masterson, Rebecca A, Brown, Joshua, Cappiello, Gregory, Chesbrough, Christian, Clark, Kristin, Coppeta, David, Frostig, Danielle, Gabutti, Michelle, Halverson, Samuel P, Hinrichsen, Erik, Kahn, Sabrina, Lambert, Madeline M, Lourie, Nathan P, Piotrowski, John, and Semisch, Christopher

Published
2022

27. Deep-Neural-Network Discrimination of Multiplexed Superconducting-Qubit States

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Lincoln Laboratory, Lienhard, Benjamin, Vepsäläinen, Antti, Govia, Luke CG, Hoffer, Cole R, Qiu, Jack Y, Ristè, Diego, Ware, Matthew, Kim, David, Winik, Roni, Melville, Alexander, Niedzielski, Bethany, Yoder, Jonilyn, Ribeill, Guilhem J, Ohki, Thomas A, Krovi, Hari K, Orlando, Terry P, Gustavsson, Simon, Oliver, William D, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Lincoln Laboratory, Lienhard, Benjamin, Vepsäläinen, Antti, Govia, Luke CG, Hoffer, Cole R, Qiu, Jack Y, Ristè, Diego, Ware, Matthew, Kim, David, Winik, Roni, Melville, Alexander, Niedzielski, Bethany, Yoder, Jonilyn, Ribeill, Guilhem J, Ohki, Thomas A, Krovi, Hari K, Orlando, Terry P, Gustavsson, Simon, and Oliver, William D

Published
2022

28. Wide-field Magnetic Field and Temperature Imaging using Nanoscale Quantum Sensors

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Mechanical Engineering, Lincoln Laboratory, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Foy, Christopher C., Zhang, Lenan, Trusheim, Matthew E, Bagnall, Kevin Robert, Walsh, Michael E, Wang, Evelyn, Englund, Dirk R., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Mechanical Engineering, Lincoln Laboratory, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Foy, Christopher C., Zhang, Lenan, Trusheim, Matthew E, Bagnall, Kevin Robert, Walsh, Michael E, Wang, Evelyn, and Englund, Dirk R.

Abstract

© 2020 American Chemical Society. The simultaneous imaging of magnetic fields and temperature (MT) is important in a range of applications, including studies of carrier transport and semiconductor device characterization. Techniques exist for separately measuring temperature (e.g., infrared (IR) microscopy, micro-Raman spectroscopy, and thermo-reflectance microscopy) and magnetic fields (e.g., scanning probe magnetic force microscopy and superconducting quantum interference devices). However, these techniques cannot measure magnetic fields and temperature simultaneously. Here, we use the exceptional temperature and magnetic field sensitivity of nitrogen vacancy (NV) spins in conformally coated nanodiamonds to realize simultaneous wide-field MT imaging at the device level. Our "quantum conformally attached thermo-magnetic"(Q-CAT) imaging enables (i) wide-field, high-frame rate imaging (100-1000 Hz); (ii) high sensitivity; and (iii) compatibility with standard microscopes. We apply this technique to study the industrially important problem of characterizing multifinger gallium nitride high-electron mobility transistors (GaN HEMTs). We spatially and temporally resolve the electric current distribution and resulting temperature rise, elucidating functional device behavior at the microscopic level. The general applicability of Q-CAT imaging serves as an important tool for understanding complex MT phenomena in material science, device physics, and related fields.

Published
2022

29. DBOS: a DBMS-oriented operating system

Author

Lincoln Laboratory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Skiadopoulos, Athinagoras, Li, Qian, Kraft, Peter, Kaffes, Kostis, Hong, Daniel, Mathew, Shana, Bestor, David, Cafarella, Michael, Gadepally, Vijay, Graefe, Goetz, Kepner, Jeremy, Kozyrakis, Christos, Kraska, Tim, Stonebraker, Michael, Suresh, Lalith, Zaharia, Matei, Lincoln Laboratory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Skiadopoulos, Athinagoras, Li, Qian, Kraft, Peter, Kaffes, Kostis, Hong, Daniel, Mathew, Shana, Bestor, David, Cafarella, Michael, Gadepally, Vijay, Graefe, Goetz, Kepner, Jeremy, Kozyrakis, Christos, Kraska, Tim, Stonebraker, Michael, Suresh, Lalith, and Zaharia, Matei

Abstract

This paper lays out the rationale for building a completely new operating system (OS) stack. Rather than build on a single node OS together with separate cluster schedulers, distributed filesystems, and network managers, we argue that a distributed transactional DBMS should be the basis for a scalable cluster OS. We show herein that such a database OS (DBOS) can do scheduling, file management, and inter-process communication with competitive performance to existing systems. In addition, significantly better analytics can be provided as well as a dramatic reduction in code complexity through implementing OS services as standard database queries, while implementing low-latency transactions and high availability only once.

Published
2022

30. Self-supervised feature extraction for 3D axon segmentation

Author

Lincoln Laboratory, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Klinghoffer, Tzofi, Morales, Peter, Park, Young-Gyun, Evans, Nicholas B, Chung, Kwanghun, Brattain, Laura J., Lincoln Laboratory, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Klinghoffer, Tzofi, Morales, Peter, Park, Young-Gyun, Evans, Nicholas B, Chung, Kwanghun, and Brattain, Laura J.

Abstract

© 2020 IEEE. Existing learning-based methods to automatically trace axons in 3D brain imagery often rely on manually annotated segmentation labels. Labeling is a labor-intensive process and is not scalable to whole-brain analysis, which is needed for improved understanding of brain function. We propose a self-supervised auxiliary task that utilizes the tube-like structure of axons to build a feature extractor from unlabeled data. The proposed auxiliary task constrains a 3D convolutional neural network (CNN) to predict the order of permuted slices in an input 3D volume. By solving this task, the 3D CNN is able to learn features without ground-truth labels that are useful for downstream segmentation with the 3D U-Net model. To the best of our knowledge, our model is the first to perform automated segmentation of axons imaged at subcellular resolution with the SHIELD technique. We demonstrate improved segmentation performance over the 3D U-Net model on both the SHIELD PVGPe dataset and the BigNeuron Project, single neuron Janelia dataset.

Published
2022

31. Progress Toward Diamond Power Field-Effect Transistors

Author

Lincoln Laboratory, Geis, Michael W., Wade, Travis C., Wuorio, Charles H., Fedynyshyn, Theodore H., Duncan, Bradley, Plaut, Maxwell E., Varghese, Joseph O., Warnock, Shireen M., Vitale, Steven A., Hollis, Mark A., Lincoln Laboratory, Geis, Michael W., Wade, Travis C., Wuorio, Charles H., Fedynyshyn, Theodore H., Duncan, Bradley, Plaut, Maxwell E., Varghese, Joseph O., Warnock, Shireen M., Vitale, Steven A., and Hollis, Mark A.

Published
2022

32. To Expedite Roadway Identification and Damage Assessment in LiDAR 3D Imagery for Disaster Relief Public Assistance

Author

Lincoln Laboratory, Mehta, Sharad, Peach, John, Weinert, Andrew, Lincoln Laboratory, Mehta, Sharad, Peach, John, and Weinert, Andrew

Abstract

Aerial surveys using LiDAR systems can play a vital role in the quantitative assessment of infrastructure damage caused by hurricanes, floods, and other natural disasters. GmAPD LiDAR provides high-resolution 3D point-cloud data which enables the surveyor to take accurate measurements of damages to roads, buildings, communication towers, power lines, etc. Due to the high point cloud density, a very large volume of data is generated during an aerial survey. The data collected during the airborne imaging is post-processed with calibration, geo-registration, and segmentation. Albeit very accurate, extracting useful information from this data is a slow and laborious process. For disaster response, methods of automating this process have spurred the development of simple, fast algorithms that can be used to recognize physical structures from the point-cloud data that can later be assessed for structural damage. In this paper, we describe an efficient algorithm to extract roadways from a massive Lidar data-set to assist the Federal Emergency Management Agency (FEMA) in assessing road conditions as a step toward helping surveyors expedite a quantitative assessment of road damages for providing and distributing public assistance for disaster relief.

Published
2022

33. Precipitation Estimation from the NASA TROPICS Mission: Initial Retrievals and Validation

Author

Lincoln Laboratory, Kidd, Chris, Matsui, Toshi, Blackwell, William, Braun, Scott, Leslie, Robert, Griffith, Zach, Lincoln Laboratory, Kidd, Chris, Matsui, Toshi, Blackwell, William, Braun, Scott, Leslie, Robert, and Griffith, Zach

Abstract

This paper describes the initial results of precipitation estimates from the Time-Resolved Observations of Precipitation structure and storm Intensity with a Constellation of Smallsats (TROPICS) Millimeter-wave Sounder (TMS) using the Precipitation Retrieval and Profiling Scheme (PRPS). The TROPICS mission consists of a Pathfinder CubeSat and a constellation of six CubeSats, providing a low-cost solution to the frequent sampling of precipitation systems across the Tropics. The TMS instrument is a 12-channel cross-track scanning radiometer operating at frequencies of 91.655 to 204.8 GHz, providing similar resolutions to current passive microwave sounding instruments. These retrievals showcase the potential of the TMS instrument for precipitation retrievals. The PRPS has been modified for use with the TMS using a database based upon observations from current sounding sensors. The results shown here represent the initial postlaunch version of the retrieval scheme, as analyzed for the Pathfinder CubeSat launched on 30 June 2021. In terms of monthly precipitation estimates, the results fall within the mission specifications and are similar in performance to retrievals from other sounding instruments. At the instantaneous scale, the results are very promising.

Published
2022

34. Weather radar network benefit model for flash flood casualty reduction

Author

Lincoln Laboratory, Cho, John Y., Kurdzo, James M., Lincoln Laboratory, Cho, John Y., and Kurdzo, James M.

Abstract

A monetized flash flood casualty reduction benefit model is constructed for application to meteorological radar networks. Geospatial regression analyses show that better radar coverage of the causative rainfall improves flash flood warning performance. Enhanced flash flood warning performance is shown to decrease casualty rates. Consequently, these two effects in combination allow a model to be formed that links radar coverage to flash flood casualty rates. When this model is applied to the present-day contiguous U.S. weather radar network, results yield a flash flood–based benefit of $316 million (M) yr−1. The remaining benefit pools are more modest ($13 M yr−1 for coverage improvement and $69 M yr−1 maximum for all areas of radar quantitative precipitation estimation improvements), indicative of the existing weather radar network’s effectiveness in supporting the flash flood warning decision process. ©2020 Keywords: radars/radar observations; regression analysis; economic value; flood events; geographic information systems (gis); societal impacts

Published
2022

35. Multi‐level Electro‐thermal Switching of Optical Phase‐Change Materials Using Graphene

Author

Massachusetts Institute of Technology. Department of Materials Science and Engineering, Lincoln Laboratory, Ríos, Carlos, Zhang, Yifei, Shalaginov, Mikhail Y, Deckoff-Jones, Skylar, Wang, Haozhe, An, Sensong, Zhang, Hualiang, Kang, Myungkoo, Richardson, Kathleen A, Roberts, Christopher, Chou, Jeffrey B, Liberman, Vladimir, Vitale, Steven A, Kong, Jing, Gu, Tian, Hu, Juejun, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Lincoln Laboratory, Ríos, Carlos, Zhang, Yifei, Shalaginov, Mikhail Y, Deckoff-Jones, Skylar, Wang, Haozhe, An, Sensong, Zhang, Hualiang, Kang, Myungkoo, Richardson, Kathleen A, Roberts, Christopher, Chou, Jeffrey B, Liberman, Vladimir, Vitale, Steven A, Kong, Jing, Gu, Tian, and Hu, Juejun

Abstract

Reconfigurable photonic systems featuring minimal power consumption are crucial for integrated optical devices in real-world technology. Current active devices available in foundries, however, use volatile methods to modulate light, requiring a constant supply of power and significant form factors. Essential aspects to overcoming these issues are the development of nonvolatile optical reconfiguration techniques which are compatible with on-chip integration with different photonic platforms and do not disrupt their optical performances. In this paper, a solution is demonstrated using an optoelectronic framework for nonvolatile tunable photonics that employs undoped-graphene microheaters to thermally and reversibly switch the optical phase-change material Ge$_2$Sb$_2$Se$_4$Te$_1$ (GSST). An in-situ Raman spectroscopy method is utilized to demonstrate, in real-time, reversible switching between four different levels of crystallinity. Moreover, a 3D computational model is developed to precisely interpret the switching characteristics, and to quantify the impact of current saturation on power dissipation, thermal diffusion, and switching speed. This model is used to inform the design of nonvolatile active photonic devices; namely, broadband Si$_3$N$_4$ integrated photonic circuits with small form-factor modulators and reconfigurable metasurfaces displaying 2$\pi$ phase coverage through neural-network-designed GSST meta-atoms. This framework will enable scalable, low-loss nonvolatile applications across a diverse range of photonics platforms.

Published
2022

36. Weather Radar Network Benefit Model for Nontornadic Thunderstorm Wind Casualty Cost Reduction

Author

Lincoln Laboratory, Cho, John Y. N., Kurdzo, James M., Lincoln Laboratory, Cho, John Y. N., and Kurdzo, James M.

Abstract

AbstractAn econometric geospatial benefit model for nontornadic thunderstorm wind casualty reduction is developed for meteorological radar network planning. Regression analyses on 22 years (1998–2019) of storm event and warning data show, likely for the first time, a clear dependence of nontornadic severe thunderstorm warning performance on radar coverage. Furthermore, nontornadic thunderstorm wind casualty rates are observed to be negatively correlated with better warning performance. In combination, these statistical relationships form the basis of a cost model that can be differenced between radar network configurations to generate geospatial benefit density maps. This model, applied to the current contiguous U.S. weather radar network, yields a benefit estimate of $207 million (M) yr−1 relative to no radar coverage at all. The remaining benefit pool with respect to enhanced radar coverage and scan update rate is about $36M yr−1. Aggregating these nontornadic thunderstorm wind results with estimates from earlier tornado and flash flood cost reduction models yields a total benefit of $1.12 billion yr−1 for the present-day radars and a remaining radar-based benefit pool of $778M yr−1., National Ocean and Atmospheric Administration (NOAA)

Published
2022

37. Dynamic Dossier in the Cloud: A Sociotechnical Architecture for a Real-Time and Metrics-Based Data Tracking System with Gene and Cell Therapies as a Case Study

Author

Lincoln Laboratory, Massachusetts Institute of Technology. Center for Biomedical Innovation, Nam, Kevin, Larholt, Kay, Hirsch, Gigi, Beninger, Paul, Fritsche, David, Shoda, Diane, Ferguson, John, Bourgeois, Florence T., Palmer, Donna, Katz, Karen, Courtney, Matt W., Lincoln Laboratory, Massachusetts Institute of Technology. Center for Biomedical Innovation, Nam, Kevin, Larholt, Kay, Hirsch, Gigi, Beninger, Paul, Fritsche, David, Shoda, Diane, Ferguson, John, Bourgeois, Florence T., Palmer, Donna, Katz, Karen, and Courtney, Matt W.

Abstract

Background Data sharing among stakeholders in the development, access, and use of drug therapies is critical but the current system and process are inefficient. Methods We take a Systems Engineering approach with a realistic use case to propose a scalable design for multi-stakeholder data sharing. Results We make three major contributions to the drug development and healthcare communities: first, a methodology for developing a multi-stakeholder data sharing system, with its focus on high-level requirements that influence the design of the system architecture and technology choice; second, the development of a realistic use case for long-term patient and therapy data tracking and sharing in the use of potentially curative and durable gene and cell therapies. Further, a bridge for the ‘awareness gap’ was found between the payer (Payer is organization which takes care of financial and operational aspects (which include insurance plans, provider network) of providing health care to US citizens. Or refer to health care insurers.) and the regulator communities by illustrating the common data tracking needs, which highlights the need for coordinated data activities; and third, a proposed system architecture for scalable, multi-stakeholder data sharing. Next steps are briefly discussed. Conclusion We present a system design for multiple stakeholders such as the payer, the regulator, the developer (drug manufacturer), and the healthcare provider to share data for their decision-making. The stakeholder community would benefit from collaboratively moving the system development proposal forward for efficient and cost-effective data sharing.

Published
2022

38. Quantum transport and localization in 1d and 2d tight-binding lattices

Author

Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, Massachusetts Institute of Technology. Department of Physics, Karamlou, Amir H, Braumüller, Jochen, Yanay, Yariv, Di Paolo, Agustin, Harrington, Patrick M, Kannan, Bharath, Kim, David, Kjaergaard, Morten, Melville, Alexander, Muschinske, Sarah, Niedzielski, Bethany M, Vepsäläinen, Antti, Winik, Roni, Yoder, Jonilyn L, Schwartz, Mollie, Tahan, Charles, Orlando, Terry P, Gustavsson, Simon, Oliver, William D, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, Massachusetts Institute of Technology. Department of Physics, Karamlou, Amir H, Braumüller, Jochen, Yanay, Yariv, Di Paolo, Agustin, Harrington, Patrick M, Kannan, Bharath, Kim, David, Kjaergaard, Morten, Melville, Alexander, Muschinske, Sarah, Niedzielski, Bethany M, Vepsäläinen, Antti, Winik, Roni, Yoder, Jonilyn L, Schwartz, Mollie, Tahan, Charles, Orlando, Terry P, Gustavsson, Simon, and Oliver, William D

Abstract

AbstractParticle transport and localization phenomena in condensed-matter systems can be modeled using a tight-binding lattice Hamiltonian. The ideal experimental emulation of such a model utilizes simultaneous, high-fidelity control and readout of each lattice site in a highly coherent quantum system. Here, we experimentally study quantum transport in one-dimensional and two-dimensional tight-binding lattices, emulated by a fully controllable 3 × 3 array of superconducting qubits. We probe the propagation of entanglement throughout the lattice and extract the degree of localization in the Anderson and Wannier-Stark regimes in the presence of site-tunable disorder strengths and gradients. Our results are in quantitative agreement with numerical simulations and match theoretical predictions based on the tight-binding model. The demonstrated level of experimental control and accuracy in extracting the system observables of interest will enable the exploration of larger, interacting lattices where numerical simulations become intractable.

Published
2022

39. Absolute Radiometric Calibration of an Imaging Spectroradiometer Using a Laboratory Detector-Based Approach

Author

Lincoln Laboratory, Wang, Zhipeng, Thome, Kurtis, Lockwood, Ronald, Wenny, Brian N., Lincoln Laboratory, Wang, Zhipeng, Thome, Kurtis, Lockwood, Ronald, and Wenny, Brian N.

Abstract

The HyperSpectral Imager for Climate Science (HySICS) is the core instrument of the Climate Absolute Refractivity and Reflectance Observatory (CLARREO) Pathfinder (CPF) mission and is currently scheduled to be launched to the International Space Station (ISS) in 2023. HySICS is an Offner–Chrisp imaging spectrometer designed to meet an unprecedented radiometric uncertainty requirement of 0.3% (k = 1) over its entire spectral range of 350–2300 nm. The approach represents the need for significant improvement over the Radiometric Calibration (RadCal) of existing space-borne spectrometers. One strategy to demonstrate that HySICS achieves this level of accuracy is through an Independent Calibration (IndCal) effort that can provide an alternative referencing RadCal, which follows a traceability chain independent of the operational RadCal of ratioing approach. The IndCal relies on a pre-launch detector-based absolute RadCal of HySICS, using a tunable laser system as source, and the system planned for the HySICS absolute RadCal is the Goddard Laser for Absolute Measurement of Radiance (GLAMR). GLAMR was developed at NASA’s Goddard Space Flight Center and has been used to calibrate multiple operational remote sensing instruments, as well as the SOlar, Lunar Absolute Reflectance Imaging Spectroradiometer (SOLARIS), a calibration demonstration system developed for the CLARREO mission. In this work, the data of SOLARIS GLAMR RadCal conducted in 2019 are processed to derive the Absolute Spectral Response (ASR) functions and other key characterization parameters of SOLARIS detectors. The results are further analyzed with the goals to plan the HySICS GLAMR RadCal, in particular to optimize its configuration, to demonstrate the traceability route to the NIST standard, and to develop the error budget of the calibration approach. The SOLARIS calibration is also compared with other source- and detector-based calibrations to validate the absolute radiometric acc

Published
2022

40. The CUORE slow monitoring systems

Author

Lincoln Laboratory, Massachusetts Institute of Technology. Department of Physics, Gladstone, Laura, Biare, D, Cappelli, L, Cushman, J S, Del Corso, F, Fujikawa, B K, Hickerson, K P, Moggi, N, Pagliarone, C E, Schmidt, B, Wagaarachchi, S L, Welliver, B, Winslow, L. A., Lincoln Laboratory, Massachusetts Institute of Technology. Department of Physics, Gladstone, Laura, Biare, D, Cappelli, L, Cushman, J S, Del Corso, F, Fujikawa, B K, Hickerson, K P, Moggi, N, Pagliarone, C E, Schmidt, B, Wagaarachchi, S L, Welliver, B, and Winslow, L. A.

Abstract

© Published under licence by IOP Publishing Ltd. CUORE is a cryogenic experiment searching primarily for neutrinoless double decay in 130 Te. It will begin data-taking operations in 2016. To monitor the cryostat and detector during commissioning and data taking, we have designed and developed Slow Monitoring systems. In addition to real-time systems using LabVIEW, we have an alarm, analysis, and archiving website that uses MongoDB, AngularJS, and Bootstrap software. These modern, state of the art software packages make the monitoring system transparent, easily maintainable, and accessible on many platforms including mobile devices.

Published
2022

42. Reconfigurable all-dielectric metalens based on phase change materials

Author

Massachusetts Institute of Technology. Department of Materials Science and Engineering, Lincoln Laboratory, Shalaginov, Mikhail Y, An, Sensong, Zhang, Yifei, Yang, Fan, Su, Peter, Liberman, Vladimir, Chou, Jeffrey B, Roberts, Christopher M, Kang, Myungkoo, Rios, Carlos, Du, Qingyang, Fowler, Clayton, Agarwal, Anuradha, Richardson, Kathleen A, Rivero-Baleine, Clara, Zhang, Hualiang, Hu, Juejun, Gu, Tian, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Lincoln Laboratory, Shalaginov, Mikhail Y, An, Sensong, Zhang, Yifei, Yang, Fan, Su, Peter, Liberman, Vladimir, Chou, Jeffrey B, Roberts, Christopher M, Kang, Myungkoo, Rios, Carlos, Du, Qingyang, Fowler, Clayton, Agarwal, Anuradha, Richardson, Kathleen A, Rivero-Baleine, Clara, Zhang, Hualiang, Hu, Juejun, and Gu, Tian

Abstract

© 2020 SPIE. All rights reserved. Optical metasurfaces, planar sub-wavelength nano-antenna arrays with the singular ability to sculpt wave front in almost arbitrary manners, are poised to become a powerful tool enabling compact and high-performance optics with novel functionalities. A particularly intriguing research direction within this field is active metasurfaces, whose optical response can be dynamically tuned post-fabrication, thus allowing a plurality of applications unattainable with traditional bulk optics. The efforts to date, however, still face major performance limitations in tuning range, optical quality, and efficiency especially for non-mechanical actuation mechanisms. In this paper, we introduce an active metasurface platform combining phase tuning covering the full 2 range and diffraction-limited performance using an all-dielectric, low-loss architecture based on optical phase change materials (O-PCMs). We present a generic design principle enabling binary switching of metasurfaces between arbitrary phase profiles. We implement the approach to realize a high-performance varifocal metalens. The metalens is constructed using Ge2Sb2Se4Te1 GSST), an O-PCM with a large refractive index contrast and unique broadband low-loss characteristics in both amorphous and crystalline states. The reconfigurable metalens features focusing efficiencies above 20 at both states for linearly polarized light and a record large switching contrast ratio (CR) close to 30 dB. We further validate aberration-free and multi-depth imaging using the metalens, which represents the first experimental demonstration of a non-mechanical active metalens with diffraction-limited performance

Published
2022

43. Hexagonal boron nitride as a low-loss dielectric for superconducting quantum circuits and qubits

Author

Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, Wang, Joel I-J, Yamoah, Megan A, Li, Qing, Karamlou, Amir H, Dinh, Thao, Kannan, Bharath, Braumüller, Jochen, Kim, David, Melville, Alexander J, Muschinske, Sarah E, Niedzielski, Bethany M, Serniak, Kyle, Sung, Youngkyu, Winik, Roni, Yoder, Jonilyn L, Schwartz, Mollie E, Watanabe, Kenji, Taniguchi, Takashi, Orlando, Terry P, Gustavsson, Simon, Jarillo-Herrero, Pablo, Oliver, William D, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, Wang, Joel I-J, Yamoah, Megan A, Li, Qing, Karamlou, Amir H, Dinh, Thao, Kannan, Bharath, Braumüller, Jochen, Kim, David, Melville, Alexander J, Muschinske, Sarah E, Niedzielski, Bethany M, Serniak, Kyle, Sung, Youngkyu, Winik, Roni, Yoder, Jonilyn L, Schwartz, Mollie E, Watanabe, Kenji, Taniguchi, Takashi, Orlando, Terry P, Gustavsson, Simon, Jarillo-Herrero, Pablo, and Oliver, William D

Abstract

Dielectrics with low loss at microwave frequencies are imperative for high-coherence solid-state quantum computing platforms. We study the dielectric loss of hexagonal boron nitride (hBN) thin films in the microwave regime by measuring the quality factor of parallel-plate capacitors (PPCs) made of NbSe$_{2}$-hBN-NbSe$_{2}$ heterostructures integrated into superconducting circuits. The extracted microwave loss tangent of hBN is bounded to be at most in the mid-10$^{-6}$ range in the low temperature, single-photon regime. We integrate hBN PPCs with aluminum Josephson junctions to realize transmon qubits with coherence times reaching 25 $\mu$s, consistent with the hBN loss tangent inferred from resonator measurements. The hBN PPC reduces the qubit feature size by approximately two-orders of magnitude compared to conventional all-aluminum coplanar transmons. Our results establish hBN as a promising dielectric for building high-coherence quantum circuits with substantially reduced footprint and, with a high energy participation that helps to reduce unwanted qubit cross-talk.

Published
2022

44. Room-temperature optomechanical squeezing

Author

LIGO (Observatory : Massachusetts Institute of Technology), Massachusetts Institute of Technology. Department of Physics, Lincoln Laboratory, Aggarwal, Nancy, Cullen, Torrey, Cripe, Jonathan, Cole, Garrett D., Lanza Jr, Robert K, Libson, Adam A., Follman, David, Heu, Paula, Corbitt, Thomas, Mavalvala, Nergis, LIGO (Observatory : Massachusetts Institute of Technology), Massachusetts Institute of Technology. Department of Physics, Lincoln Laboratory, Aggarwal, Nancy, Cullen, Torrey, Cripe, Jonathan, Cole, Garrett D., Lanza Jr, Robert K, Libson, Adam A., Follman, David, Heu, Paula, Corbitt, Thomas, and Mavalvala, Nergis

Abstract

© 2020, The Author(s), under exclusive licence to Springer Nature Limited. Squeezed light—light with quantum noise lower than shot noise in some quadratures and higher in others—can be used to improve the sensitivity of precision measurements. In particular, squeezed light sources based on nonlinear optical crystals are being used to improve the sensitivity of gravitational wave detectors. In optomechanical squeezers, the radiation-pressure-driven interaction of a coherent light field with a mechanical oscillator induces correlations between the amplitude and phase quadratures of the light, which induce the squeezing. However, thermally driven fluctuations of the mechanical oscillator’s position make it difficult to observe the quantum correlations at room temperature and at low frequencies. Here, we present a measurement of optomechanically squeezed light, performed at room temperature in a broad band near the audio-frequency regions relevant to gravitational wave detectors. We observe sub-Poissonian quantum noise in a frequency band of 30–70 kHz with a maximum reduction of 0.7 ± 0.1 dB below shot noise at 45 kHz. We present two independent methods of measuring this squeezing, one of which does not rely on the calibration of shot noise.

Published
2022

45. AI-Enabled, Ultrasound-Guided Handheld Robotic Device for Femoral Vascular Access

Author

Lincoln Laboratory, Brattain, Laura J., Pierce, Theodore T., Gjesteby, Lars A., Johnson, Matthew R., DeLosa, Nancy D., Werblin, Joshua S., Gupta, Jay F., Ozturk, Arinc, Wang, Xiaohong, Li, Qian, Telfer, Brian A., Samir, Anthony E., Lincoln Laboratory, Brattain, Laura J., Pierce, Theodore T., Gjesteby, Lars A., Johnson, Matthew R., DeLosa, Nancy D., Werblin, Joshua S., Gupta, Jay F., Ozturk, Arinc, Wang, Xiaohong, Li, Qian, Telfer, Brian A., and Samir, Anthony E.

Abstract

Hemorrhage is a leading cause of trauma death, particularly in prehospital environments when evacuation is delayed. Obtaining central vascular access to a deep artery or vein is important for administration of emergency drugs and analgesics, and rapid replacement of blood volume, as well as invasive sensing and emerging life-saving interventions. However, central access is normally performed by highly experienced critical care physicians in a hospital setting. We developed a handheld AI-enabled interventional device, AI-GUIDE (Artificial Intelligence Guided Ultrasound Interventional Device), capable of directing users with no ultrasound or interventional expertise to catheterize a deep blood vessel, with an initial focus on the femoral vein. AI-GUIDE integrates with widely available commercial portable ultrasound systems and guides a user in ultrasound probe localization, venous puncture-point localization, and needle insertion. The system performs vascular puncture robotically and incorporates a preloaded guidewire to facilitate the Seldinger technique of catheter insertion. Results from tissue-mimicking phantom and porcine studies under normotensive and hypotensive conditions provide evidence of the technique’s robustness, with key performance metrics in a live porcine model including: a mean time to acquire femoral vein insertion point of 53 ± 36 s (5 users with varying experience, in 20 trials), a total time to insert catheter of 80 ± 30 s (1 user, in 6 trials), and a mean number of 1.1 (normotensive, 39 trials) and 1.3 (hypotensive, 55 trials) needle insertion attempts (1 user). These performance metrics in a porcine model are consistent with those for experienced medical providers performing central vascular access on humans in a hospital.

Published
2022

46. Multimodal Representation Learning via Maximization of Local Mutual Information

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Lincoln Laboratory, Liao, Ruizhi, Moyer, Daniel, Cha, Miriam, Quigley, Keegan, Berkowitz, Seth, Horng, Steven, Golland, Polina, Wells, William M, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Lincoln Laboratory, Liao, Ruizhi, Moyer, Daniel, Cha, Miriam, Quigley, Keegan, Berkowitz, Seth, Horng, Steven, Golland, Polina, and Wells, William M

Published
2022

47. Band-Averaged Response Sensitivity Study of an Imaging Spectrometer for the CLARREO Pathfinder Mission

Author

Lincoln Laboratory, Salehi, Fatholah, Thome, Kurtis, Wenny, Brian N., Lockwood, Ronald, Wang, Zhipeng, Lincoln Laboratory, Salehi, Fatholah, Thome, Kurtis, Wenny, Brian N., Lockwood, Ronald, and Wang, Zhipeng

Abstract

Prelaunch absolute, SI-traceable radiometric calibration of satellite-based sensors is key to ensuring the utility of imaging spectrometer-based data products. The development of detector-based calibration techniques leads to the feasibility of meeting the 0.3% uncertainty level needed to provide climate quality data sets. Detector-based calibration is a method in which a well-understood and stable transfer radiometer is calibrated in a standards laboratory to SI-traceable standards, and transported to a facility calibrating a sensor of interest. The transfer radiometer provides the calibration of the source used in the radiometric calibration. A detector-based calibration approach is part of the prelaunch calibration of the CLARREO (Climate Absolute Radiance and Refractivity Observatory) Pathfinder (CPF) sensor with the Goddard Laser for Absolute Measurement of Radiance (GLAMR) system. The SI-traceability of GLAMR is through the electric watt as part of the absolute radiometric calibration of the detectors at the National Institute of Standards and Technology using the Primary Optical Watt Radiometer. The current work uses GLAMR data collected with a visible and near-infrared imaging spectrometer calibration demonstration system to develop a source/sensor modeled calibration data set as part of a sensitivity study to evaluate uncertainties from the spectral sampling and processing methods that accompany the GLAMR calibration process. The spectral “supersets” include realistic instrumental features as well as effects from the GLAMR source. The methods needed to ensure that spurious sensor and GLAMR data are excluded are described. Results are given from the sensitivity study related to GLAMR spectral sampling and signal-to-noise ratio (SNR) effects, sensor integration time, and frame averaging of the imaging spectrometer data. The study shows that the 6 nm bandwidth sensor simulation requires a 1 nm spectral sampling of the GLAMR source with a radiance l

Published
2022

48. Realization of In-Band Full-Duplex Operation at 300 and 4.2 K Using Bilateral Single-Sideband Frequency Conversion

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, Yi, Xiang, Wang, Jinchen, Colangelo, Marco, Wang, Cheng, Kolodziej, Kenneth E, Han, Ruonan, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, Yi, Xiang, Wang, Jinchen, Colangelo, Marco, Wang, Cheng, Kolodziej, Kenneth E, and Han, Ruonan

Published
2022

49. Quantifying Bias in a Face Verification System

Author

Lincoln Laboratory, Frisella, Megan, Khorrami, Pooya, Matterer, Jason, Kratkiewicz, Kendra, Torres-Carrasquillo, Pedro, Lincoln Laboratory, Frisella, Megan, Khorrami, Pooya, Matterer, Jason, Kratkiewicz, Kendra, and Torres-Carrasquillo, Pedro

Abstract

Machine learning models perform face verification (FV) for a variety of highly consequential applications, such as biometric authentication, face identification, and surveillance. Many state-of-the-art FV systems suffer from unequal performance across demographic groups, which is commonly overlooked by evaluation measures that do not assess population-specific performance. Deployed systems with bias may result in serious harm against individuals or groups who experience underperformance. We explore several fairness definitions and metrics, attempting to quantify bias in Google’s FaceNet model. In addition to statistical fairness metrics, we analyze clustered face embeddings produced by the FV model. We link well-clustered embeddings (well-defined, dense clusters) for a demographic group to biased model performance against that group. We present the intuition that FV systems underperform on protected demographic groups because they are less sensitive to differences between features within those groups, as evidenced by clustered embeddings. We show how this performance discrepancy results from a combination of representation and aggregation bias.

Published
2022

50. 3D integration and measurement of a semiconductor double quantum dot with a high-impedance TiN resonator

Author

Lincoln Laboratory, Massachusetts Institute of Technology. Research Laboratory of Electronics, Holman, Nathan, Rosenberg, D, Yost, D, Yoder, JL, Das, R, Oliver, William D, McDermott, R, Eriksson, MA, Lincoln Laboratory, Massachusetts Institute of Technology. Research Laboratory of Electronics, Holman, Nathan, Rosenberg, D, Yost, D, Yoder, JL, Das, R, Oliver, William D, McDermott, R, and Eriksson, MA

Abstract

AbstractOne major challenge to scaling quantum dot qubits is the dense wiring requirements, making it difficult to envision fabricating large 2D arrays of nearest-neighbor-coupled qubits necessary for error correction. We describe a method to ameliorate this issue by spacing out the qubits using superconducting resonators facilitated by 3D integration. To prove the viability of this approach, we use integration to couple an off-chip high-impedance TiN resonator to a double quantum dot in a Si/SiGe heterostructure. Using the resonator as a dispersive gate sensor, we tune the device down to the single electron regime with an SNR = 5.36. Characterizing the individual systems shows 3D integration can be done while maintaining low-charge noise for the quantum dots and high-quality factors for the superconducting resonator (single photon QL = 2.14 × 104 with Qi ≈ 3 × 105), necessary for readout and high-fidelity two-qubit gates.

Published
2022

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