Lawrence Livermore National Laboratory and Tyvak Nano-Satellite Systems Announce Agreement to Develop Innovative Telescopes for Nanosatellites

Lawrence Livermore National Laboratory (LLNL) and Tyvak Nano-Satellite Systems, Inc. have reached a cooperative research and development agreement (CRADA) to develop innovative compact and robust telescopes for nanosatellites.

The four-year, $2 million CRADA will combine LLNL’s Monolithic Telescope (MonoTele) technology with Tyvak’s expertise producing high- reliability spacecraft.

In the future, the advanced optical imaging payloads may be employed to collect information for remote sensing data users.

The MonoTele consists of a space telescope fabricated from a single, monolithic fused silica slab, allowing the optic lens to operate within tight tolerances. This approach does not require on-orbit alignment, greatly simplifying spacecraft design and favorably affecting spacecraft size, weight and power needs.

“I’m excited about this technology transitioning from LLNL to space demonstration and eventual commercial use,” said Alex Pertica, the deputy program leader for LLNL’s Space Science and Security Program (SSSP).

Tyvak will provide the spacecraft and payload, consisting of the MonoTele, sensor, and electronics, ensuring survivability in a demanding vibration environment during launch and wide-ranging temperatures on-orbit.

LLNL will then apply its knowledge of novel optical payloads to develop, test, and process data gathered from the sensors.

“We are delighted to have formalized this collaborative effort with LLNL to demonstrate and commercialize advanced optical imaging technology,” said Anthony Previte, Tyvak’s CEO. “Together we will enable end users to achieve their mission goals in many space-based markets.”

 Developed by LLNL over the past eight years, the MonoTele space telescopes range in size from one inch (called the mini-monolith) to 14 inches.

The MonoTele technology provides imaging for nanosatellites, about the size of a large shoebox and weighing less than 22 pounds, and microsatellites, about the size of a dorm refrigerator and weighing up to several hundred pounds.

LLNL researchers undertook the development of the tiny one-inch, mini-monolith for use in star trackers, a component that every satellite has one or more of, and is used to find the satellite’s “attitude” or orientation. Attached to the satellite’s body, the star trackers compare the satellite’s position relative to the position of the stars to determine their orientation.

 “Several telescopes with the MonoTele technology have flown in space. They’ve performed very well,” Pertica said, adding that the one-inch, mini-monolith version is now flying aboard Tyvak-0129. The technology’s first space mission was the GEOstare satellite, which launched in January 2018.

Typically, space telescopes have two optical mirrors – a larger primary mirror and a smaller secondary mirror – that face each other. If the mirrors go out of alignment, the image becomes fuzzy.

To keep the mirrors in alignment, a metering structure is typically employed to maintain the mirrors in place. But metering structures can be expensive and can go out of alignment.

To solve this problem, LLNL optical scientist Brian Bauman came up with the idea of the MonoTele – replacing the two mirrors and metering structure with one solid piece of glass, with optical shapes and reflective coatings at both ends of the glass.

The MonoTele concept was inspired by the design of the mirrors used for the Large Synoptic Survey Telescope that is under construction in Chile, due to come online in 2023 and expected to image some 20 billion galaxies.

Under this CRADA, LLNL and Tyvak expect to develop additional MonoTele-type telescopes capable of operating in other wavelength bands, such as ultraviolet and short-wave infrared, and as a spectrometer instrument.

The telescopes, which would be demonstrated in space, also would feature compact and low-power focus mechanisms for missions requiring agile optics technology.

The MonoTele nanosatellite imaging payloads can be used across multiple applications and will serve Earth observation, space situational awareness, and satellite navigation initiatives. “Partnering under a CRADA with outside industry was the natural next step for commercializing the technology,” said David Dawes, a business development executive in LLNL’s Innovation and Partnerships Office. “We look forward to working with Tyvak.”

“The CRADA gives Tyvak the option to license LLNL intellectual property (IP) or joint IP developed under this collaboration, in addition to any of the Lab’s existing background IP required to practice the subject inventions,” Dawes added.

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