Tech Notes

Tech Notes report on technical accomplishments and capabilities of MIT Lincoln Laboratory.

 

Airborne Ladar Imaging Research Testbed

ALIRT iconThe Airborne Ladar Imaging Research Testbed (ALIRT) is an airborne three-dimensional imaging laser radar system that can rapidly collect high-resolution maps of wide-area terrain from altitudes up to 9000 m and decimeter accuracy from altitudes of 3000 m. This technology won a 2011 R&D 100 Award.

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Multifunction Phased Array Radar Panel
MPAR icon

An innovative design exploits dual polarization and digital beamforming to provide a radar solution for simultaneous aircraft surveillance and weather sensing. This technology, a 2011 R&D 100 Award winner, also received an R&D Magazine's Editor's Choice Award.

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Parallel Vector Tile Optimizing Library
PVTOL icon

Researchers at MIT Lincoln Laboratory developed the Parallel Vector Tile Optimizing Library to address a
primary challenge faced by developers of embedded signal processing applications: how to write programs at a high level while still achieving performance and preserving the portability of the code across platforms. This technology won a 2011 R&D 100 Award.

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PANTHER: Rapidly identifying biological agents in aerosols
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The threat of airborne hazardous biological agents within a building or in locations of high population density stresses the need for rapid, sensitive identification of the responsible biological agents. Lincoln Laboratory developed the Pathogen Analyzer for Threatening Environmental Releases to provide rapid bioidentification. This technology won a 2011 R&D 100 Award.

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Reagan Test Site Distributed Operations

Icon for Reagan Test Site Distributed OpsMIT Lincoln Laboratory is contributing to a transformational program to fundamentally change the mission execution and operations at the Reagan Test Site on the Kwajalein Atoll, Marshall Islands. When the program is completed, operations at the Reagan Test Site will be able to be managed from the continental United States.

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Miniature Radio Frequency Receivers

Icon of a mini RF receiverThe Lincoln Laboratory four-channel miniature radio frequency receiver implemented on a single chip detects low-level signals across a wide frequency range in the presence of many interferers. It outperforms existing commercial receiver systems by leveraging improvements in silicon germanium semiconductors. This technology won a 2010 R&D 100 Award.

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Next-Generation Incident Command System

LDDRS iconLincoln Laboratory's integrated sensing and command-and-control system enables a coordinated, collaborative disaster response by improving situational awareness.

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Orthogonal Transfer Array: Enabling wide-field imaging

Thumbnail of orthogonal transfer arrayArrays of unique charge-coupled devices developed at Lincoln Laboratory are making it possible for the world's largest focal plane to image vaster expanses of the night sky than ever before.

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Superconducting Nanowire Photodetector Arrays

Icon of a micrograph of a superconducting photodetector arrayOvercoming basic physical limitations on individual detector speed enables broad-band single-photon detection with high efficiency and low noise at record-high rates exceeding one billion photons per second. This technology won a 2010 R&D 100 Award.

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Runway Status Lights

Icon of airport runwayPreventing runway incursions that lead to accidents has been on the National Transportation Safety Board's "Most Wanted List" for nearly two decades. To prevent incursions on airport runways, MIT Lincoln Laboratory developed a status lights system that uses existing airport surveillance technology in conjunction with advanced data-fusion techniques and state logic. This technology won a 2010 R&D 100 Award.

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Nonlinear Equalization for Receiver Dynamic Range Extension

Icon of a chipMIT Lincoln Laboratory has achieved significant increases in receiver dynamic range by applying nonlinear equalization techniques.

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Digital Focal-Plane Arrays

Thumbnail of a DFPA chipLincoln Laboratory's digital focal-plane array technology is improving the long-range infrared capabilities of detectors used in wide-area imaging and surveillance applications. This technology won a 2010 R&D 100 Award.

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Specialized avalanche photodiode arrays enable adaptive optics uses

GMAPD iconAdaptive optics requires detectors with high fill factor—as an incident light spot shifts, so does the pattern of detector responses. Lincoln Laboratory has demonstrated an array of Geiger-mode avalanche photodiodes specifically tailored for adaptive optics uses. This technology won a 2010 R&D 100 Award.

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Extended Space Sensors Architecture

ESSA iconLincoln Laboratory is demonstrating a service-oriented network architecture that enables the space community to share information and services from the varied systems of the Space Surveillance Network.

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CANARY: Technology for rapidly identifying biological agents

CANARY iconThe need for rapid, sensitive identification of biological agents is being addressed by Lincoln Laboratory with unique instruments that use the Cellular Analysis and Notification of Antigen Risks and Yields (CANARY) technology.

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Technology Transfer: A vital part of the Laboratory’s mission

tech transfer iconLincoln Laboratory's technology transfer activities contribute significantly to the expansion of scientific knowledge and the promotion of industry solutions to defense and civil sector problems.

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Multiple-Antenna Techniques for Wireless Communications

Multiantenna iconMultiple-antenna technology is a rich area of research. Whether for future military wireless networks, soldier radios, autonomous sensors, or robotics, the demand for improved performance may be met with multiple-antenna communication links and the advanced technology making those links effective.

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Micropumps: Innovations to transport fluids in microchips

micropumps iconMicrofluidics, the science of systems that can manipulate extremely small volumes of liquids, has been named by MIT Technology Review as one of the ten technologies that will change the world.

However, while microfluidic systems have enabled familiar systems such as inkjet printers and not-so-familiar systems such as microchips used for analysis of biological samples (often dubbed "labs-on-a-chip"), microfluidics has not yet lived up to its predicted potential. Lincoln Laboratory researchers are working to change that.

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