Computer Science Capstone Design
Capstone Project Description, Spring 2008

Automated Geometric Centroiding System for the Alignment of the Navy Prototype Optical Interferometer

Project Overview:

The Navy Prototype Optical Interferometer (NPOI), located just outside Flagstaff, Arizona, consists of 170 precision flat mirrors mounted inside 9000 cubic feet of vacuum, positioned along a 400 meter diameter Y-shaped array. Quantifiable precision alignment of each mirror is critical to the efficient operation of the interferometer telescope system; light must be very accurately directed through the system. When the array was built, each mirror was precisely positioned. Over time, however, with natural thermal variations, the pointing of the mirrors drifts out of tolerance and requires correcting. Depending on temperature variations and other factors, this realignment process has to be undertaken as often as every night. This process is currently done manually, with the human eyeball and human operation of stepper motors to tweak the mirrors. Not only does this take much time and effort, it is also not as accurate as one could hope for; human visual systems are limited and "bump and check again" human adjustment of stepper motors is error-prone.

This project explores improvement of this process by replacing the human element with an automated system. In particular, we would like to explore using a CCD camera to perceive alignment, calculate corrections, and then send control signals to the stepper motors. The goal is to make the re-alignment process very fast, efficient and automated so that, even during nightly astronomical observations, it is possible to quickly check and re-adjust the mirrors in the optical train.

More generally, we would like to support a more diverse se of science programs and expansion of capabilities at the NPOI, which will require nightly reconfigurations of optical mounts within the vacuum system. As part of this process, efficient alignment of the optical train is required.

How the alignment system works: The basic concept is that alignment is by sighting a special LED target. A "pop-up" light emitting diode (LED) (mounted on a motorized target arm) is attached to each mirror mount and, when popped up, aligns perfectly to indicate the mirror’s center point. A focusable precision alignment telescope, mounted in a v-block assembly at the other (distant) end of the array galley, is employed as the basic alignment tool. Presently, the human eye acts as the primary detector and a subjective decision is made regarding the spatial error between the center of the LED target and the crosshairs of the telescope. The human eye detector is adequate for building and verifying rough alignments. However, the system is inefficient, slow to use, and requires much skill and effort to achieve optimal alignments, and is therefore inadequate for nightly reconfigurations and precision alignments.

We require the development of an automated imaging/centroiding system that has the following capabilities:

• Quantify the error in alignments in near real time
• Fast, efficiency and reliable
• User-friendly interface
• Adaptable to future expansions
• Graphical user interface (GUI) such that a technician can operate the system and interpret the results
• Expandable such that ultimately it will interface with computerized control electronics, i.e., will control the actal stepper motors, to form a fully automated alignment system.    

For more detailed information about the system and related alignment challenges, we include two recent papers submitted to recent SPIE conferences: Paper 1 and Paper 2. Both are Word documents.