Laboratories

  • The Advanced Materials Processing Laboratory’s research includes brazing alloys, composite coatings, enhancement of forgings, hydrogen permeating membranes, and ultrasonic weldings.
  • The Analog & Mixed-Signal Integrated Circuit (AMSIC) Research Laboratory develops design methods for analog, radio frequency, and mixed-signal integrated circuits with a focus on low-power wireless communication devices, built-in testing and calibration techniques for systems-on-a-chip, and medical applications.
  • The Biomedical Mechatronics Laboratory specializes in the design, control and testing of novel robotic systems.
  • The Biomedical Signal Processing Laboratory develops signal and image processing algorithms to extract useful information from biomedical and biological signals.
  • The Bio-Nano Robotics Laboratory uses the tools of molecular biology and protein engineering to identify, express, and purify natural protein-based nanoActuator and nanoSensor motifs.
  • The Cognitive Systems Laboratory performs research at the intersection of signal processing, machine learning, and their applications to contemporary problems in biological sciences and biomedical engineering.
  • The Complex Dynamic Systems and Control Laboratory has the primary focus of understanding the stability mechanisms of linear time-invariant (LTI) systems with “multiple delays”.
  • The Directed Assembly of Particles and Suspensions (DAPS) laboratory research starts with colloids, bioparticles, polymers and emulsions as building blocks. These can be manipulated and functionalized to produce advanced materials.
  • The Electron Devices Group Laboratory capabilities include microfabrication, microwave materials fabrication and characterization, plasma measurements and processing, noise measurements, microwave device characterization, and VLSI design.
  • The Extracellular Matrix Engineering Research Laboratory (EMRL) determines how collagen is aligned naturally by cells and how we can align it ourselves.
  • The HPVLSI Laboratory focuses on methods and tools for the design of high-speed and low-power digital/analog integrated circuits.
  • The Intelligent Human-Machine Systems (IHMS) Laboratory has the goal of developing intelligent machine systems that assist and interact with human operators.
  • Jung’s Research Group focuses on controlled synthesis, assembly, and integration of low dimensional nanomaterials for nanoelectronics, flexible devices, and biomedical applications.
  • The Laboratory for Information and Software Fusion (LISF) is pursuing a control theory based approach to self-controlling software.
  • The Laboratory for Responsible Manufacturing (LRM) conducts research in areas such as Environmentally Conscious Manufacturing, Mass Customization, and Sensor-assisted Monitoring and Diagnosis.
  • The Laminar Burning Speed Laboratory conducts fundamental research in flame speed measurement and autoignition using constant volume vessel with high speed photography.
  • Macromolecular Innovations in Nanomaterial Utilizing Systems Laboratory (MINUS Lab) is focused on the study of polymer-based nano-carbon composites.
  • The Nanoelectromechanical Systems Laboratory (NEMSLab) conducts research in Nano fabrication, NEMS sensors for physical, chemicaland biological detection, Radio Frequency (RF) NEMS devices and NEMS metamaterials.
  • The Nanomedical System Laboratoryconducts research on nanobioscience involving artificial cell membrane nanoarray-based-in-vitro drug discovery, single biomolecule recognition using nanoarray electrochemical analysis, and nanosafety based on material chemistry for next-generation medical industry.
  • The Northeastern University Computer Architecture Research Group (NUCAR) pursues research questions in the areas of Computer Architecture, Performance Evaluation, Emerging Software Technologies, and Advanced Storage Systems.
  • The Northeastern University Energy-efficient and Secure Systems (NUEESS) laboratory conducts research in the design and optimization of energy-efficientembedded system and sensor networks, secure computer architecture and systems,and hardware-oriented security and trust issues.
  • The Optical Science Laboratory uses light in combination with another type of wave, such as microwave or ultrasound, for biological and medical imaging, landmine detection, and remote sensing of the environment.
  • The Piezoactive Systems Laboratory (PSL) mainly focuses on research activities involving modeling and control of next-generation micro/nano-electromechanical sensors and actuators, as well as control and manipulation at the micro/nanoscale with new applications ranging from precision manipulation to imaging and sensing.
  • The Power Electronics Research Group improves the performance and reliability of high-frequency switch-mode converters.
  • The Quality and Productivity Laboratory conducts theoretic and applied research in statistical quality control, experimental design, process improvement, and probabilistic optimization in a wide range of industrial and service applications.
  • The Reconfigurable Computing Laboratory focuses on mapping image and signal processing applications to reconfigurable hardware.
  • The Systems Modeling And Radio Technology (SMART) Laboratory is a partnership between Northeastern University and Mathworks to develop cutting edge research and innovative curricula in a variety of areas related to technical and scientific computing, heterogeneous processing, simulation and model-based design.
  • The Thermodynamics and Combustion Laboratory concentrates on thermodynamics and combustion. The thermodynamic research involves equilibrium and non-equilibrium thermodynamics dealing with fundamental relations and determination of Onsager’s coefficients for reacting gas mixtures.
  • The Virtual Environment Laboratory builds virtual environments, develops and implements scenarios, measures driver performance and designs and develops driving simulators.