The Infrared Imaging Spectrograph (IRIS) for TMT: Multi-tiered Wavefront Measurements and Novel Mechanical Design

TL;DR

This paper introduces the IRIS instrument for TMT, highlighting its innovative mechanical design, wavefront sensing capabilities, and strategies for precise image stabilization within strict mass and structural constraints.

Contribution

It presents a novel, lightweight support structure and rotator using composite materials, and details the integration of advanced wavefront sensing and image stabilization techniques.

Findings

30% mass reduction achieved for support structure and rotator

Effective low-order aberration sensing with three guide star sensors

Strategies developed for precise source acquisition and image stabilization

Abstract

The InfraRed Imaging Spectrograph (IRIS) will be the first light adaptive optics instrument on the Thirty Meter Telescope (TMT). IRIS is being built by a collaboration between Caltech, the University of California, NAOJ and NRC Herzberg. We present novel aspects of the Support Structure, Rotator and On-Instrument Wavefront Sensor systems being developed at NRC Herzberg. IRIS is suspended from the bottom port of the Narrow Field Infrared Adaptive Optics System (NFIRAOS), and provides its own image de-rotation to compensate for sidereal rotation of the focal plane. This arrangement is a challenge because NFIRAOS is designed to host two other science instruments, which imposes strict mass requirements on IRIS. We have been tasked with keeping the instrument mass under seven tonnes which has resulted in a mass reduction of 30 percent for the support structure and rotator compared to the most recent IRIS designs. To accomplish this goal, while still being able to withstand earthquakes, we developed a new design with composite materials. As IRIS is a client instrument of NFIRAOS, it benefits from NFIRAOS's superior AO correction. IRIS assists this correction by sensing low-order aberrations with an On-Instrument Wavefront Sensor (OIWFS). The OIWFS consists of three independently positioned natural guide star wavefront sensors that patrol a 2-arcminute field of view. We expect tip-tilt measurements from faint stars within the IRIS imager focal plane will further stabilize the delivered image quality. We describe how the use of On-Detector Guide Windows (ODGWs) in the IRIS imager can be incorporated into the AO correction. Finally, we present our strategies for acquiring and tracking sources with this complex AO system, and for mitigating and measuring the various potential sources of image blur and misalignment due to properties of the mechanical structure and interfaces. (Abridged)