SOURCE: Boston Micromachines

June 24, 2009 11:30 ET

Boston Micromachines Deformable Mirror Used in Subaru Observatory Extreme Adaptive Optics Project

Subaru Coronagraphic Extreme-AO Project Uses MEMS Deformable Mirror in Direct Imaging Technique

CAMBRIDGE, MA--(Marketwire - June 24, 2009) - Boston Micromachines Corporation, a leading provider of MEMS-based deformable mirror (DM) products for adaptive optics systems, announced today that its Kilo-DM is being used in the Subaru Coronagraphic Extreme-AO project (SCExAO) in a direct imaging technique in the search for extrasolar planets. This system, which is aimed at imaging faint planets around stars, is currently under assembly and slated for on sky use in 2010.

The SCExAO system combines Boston Micromachines' Kilo-DM, a 1020-actuator MEMS deformable mirror for high accuracy wavefront correction and a high performance Phase Induced Amplitude Apodization (PIAA) coronagraph. SCExAO's goal is to view planets much fainter and closer to their stars than possible with current techniques. The foremost limit in current adaptive optics systems is the difficulty in determining the difference between a planet image and "speckles" which are actually starlight scattered across the image because of small residual wavefront error.

"The Kilo-DM enables us to actively test if light is starlight speckles or a real planet, using the fundamental property that starlight interferes with speckles, but planet light will not," said Olivier Guyon, astronomer at the Subaru Observatory and the University of Arizona. "With its high number of actuators, the Kilo-DM gives us the ability to rapidly modulate the wavefront in a way which tests, for each point in the image, if the light we are seeing is starlight or planet light. Laboratory tests have validated this new technique. We can measure speckles almost a billion times fainter than the central source."

"The discovery of extrasolar planets is an exciting field and we are happy that the excellent team at the Subaru Observatory has selected our mirrors for use in their system," said Paul Bierden, president and CEO of Boston Micromachines. "I believe that our deformable mirrors can be an enabling technology to help meet the challenging requirements of astronomical research."

Work is also underway with the University of Arizona to use the same technique on the Large Binocular Telescope and discussions are in process for high performance exoplanet imagers on future Extremely Large Telescopes.

The Kilo-DM is an enabling component for high spatial resolution wavefront control. It offers 1020 actuators in a 32x32 array, with clear aperture of 9.3 mm with 1.5 microns of deflection making it ideal for challenging applications. The systems include a deformable mirror, high speed controller, mirror interface, and high-density electrical interconnects.

About Boston Micromachines Corporation

Founded in 1999, Boston Micromachines Corporation (BMC) is the leading provider of advanced microelectromechanical systems (MEMS)-based mirror products for use in commercial adaptive optics systems, applying wavefront correction to produce high resolution images of the human retina and enhance images blurred by the Earth's atmosphere. The company's suite of award-winning compact deformable mirror (DM) products is the most cost-effective, highest performance mirrors in the market today. They are widely used in vision science applications such as advanced optic retinal imaging, long range laser communications, and astronomy, including NASA's search for planets in other solar systems. Customers include leading manufacturers of optical imaging and communication systems, governmental agencies and contractors, and vision science research laboratories worldwide, including NASA, UCal Berkeley, Lockheed Martin and Boston University. Located in Cambridge, Massachusetts, BMC is privately held and also offers custom designed manufacturing services. For more information on BMC, please visit www.bostonmicromachines.com.

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