Fast Fiber-Coupled Imaging of X-Rays Events
Award last edited on: 2/23/2018

Sponsored Program
Awarding Agency
Total Award Amount
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Solicitation Topic Code
Principal Investigator
Samuel Brockington

Company Information

HyperV Technologies Corporation

13935 Willard Road
Chantilly, VA 20151
   (703) 378-4882
Location: Single
Congr. District: 10
County: Fairfax

Phase I

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HyperV Technologies Corp. proposes to construct a long-record-length, fiber-coupled, fast imaging diagnostic for recording X-ray back-lit material flows and X-ray emission events. X-ray imaging of material flows in detonation fronts and combustion through protective housings has many important aerospace, industrial and defense implications. First HyperV will design, construct and test, in conjunction with UAH, a single fiber coupled X-ray scintillator pixel. Silicon Photo-multipliers will be investigated to maximize channel properties for the accepted cost and desired scalability. Next we will develope an X-ray imager of at least 16 pixels for observing X-ray backlit material flows based off of the single channel experiments. A camera performance of at least 2500 frames at 10 Megaframes per second with at least 12-16 bits per pixel will be targeted. X-ray emission from backlighter will be shone through a rocket motor and projected onto a scintillator. The optical emission from the scintillator is then observed by a fiber imaging grid. The imaging grid would then couple light to a bank of amplified SiPM pixels with integrated analog gain and data acquisition. HyperV has already demonstrated as part of previous work a two clock domain technique for using slow cheap micro-controllers to manage high time resolution data acquisition over long record-length with a low cost digital backend. HyperV has also demonstrated that this back end can be used to observe SiPM as well as photodiode detectors. We propose now to extend these techniques observe X-ray induced emission of scintillator materials for performing time resolved imaging of X-rays. This small scale imager would then be used to observe material flows in rocket motors in the UAH X-ray laboratory as a demonstration of the diagnostics capability.

Phase II

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