Following a successful second IRIS Preliminary Design Phase Review (PDR-2) at the TMT Project Office in Pasadena, IRIS is proceeding into its Final Design phase. The focus of the second review, held in September, involved an assessment of the IRIS software (including its data reduction system) and electrical design (including its detectors) as well as programmatic aspects spanning project cost and overall schedule. IRIS is a first light instrument designed to operate in the near-infrared (0.84-2.4 μm). It will enable the broad study of astronomical objects by providing data sets that are exquisite in their detail. It will achieve an angular resolution 10 times better than images from the Hubble Space Telescope. As one of the highest angular resolution near-infrared instruments in the world, it will help usher in a new era of astronomical study. The features of the design will enable a vast range of science goals covering numerous astrophysical domains including: solar system science, extrasolar planet studies, star formation processes, the physics super-massive black-holes and the composition and formation of galaxies, from our local neighborhood to high-redshift galaxies. Review participants included members of the IRIS team, external subject matter experts and key stakeholders. The review panel was chaired by Richard “Ric” Davies, senior scientist at Max-Planck Institute and the principal investigator of the Multi-AO Imaging Camera for Deep Observations (MICADO), one first light instrument for the E-ELT. In its initial feedback, the review board congratulated and acknowledged the IRIS team on the quality of the presentations and documentation delivered, recognizing the excellent work undertaken by the instrument team to complete the preliminary design phase. The review featured a thorough assessment of the readiness of the IRIS software design as well as the system’s electrical plan and a revisiting of its operational concepts. Additionally, the team presented its first quality assurance and safety plans. Lastly, PDR-2 also saw the team generate a cost proposal as well as produce its final design phase schedule. During the latter part of the preliminary design phase, the IRIS science team greatly expanded upon the instrument’s operational concepts, specifically addressing the steps and system interactions involved in preparing for and performing end-to-end observations. To this end, a thorough subset of the envisioned IRIS science cases walked through the anticipated software sequences. When delivered, IRIS will operate from 0.84 µm to 2.4 µm and offer diffraction-limited imaging and integral-field spectroscopy at wavelengths greater than 1 µm. The design will feature an Imager with a field-of-view of 34”x34” arcsec which relays light into the Integral Field Spectrograph (IFS). The IFS hosts two slicing techniques to sample the delivered field, each of these provides two plate scale options for a total of four modes. Of these, the lenslet channel will handle the finest plate scales; whereas, the slicer channel will provide coverage for the coarser ones. The IFS will support moderate spectral resolutions of R = 4,000. IRIS is being designed to take true advantage of all the gains afforded by a 30m class telescope. In its highest spatial sampling, the IFS will yield upwards of 14,000 individual simultaneous spectra. As one of TMT’s first-light instruments, IRIS needs to be versatile, and to this end, the observing modes are enriched by the instrument’s complement of 60 filters and 14 gratings. The IRIS collaborating institutions include The California Institute of Technology (CIT); The Nanjing Institute of Astronomical Optics and Technology (NIAOT); The National Astronomical Observatory of Japan (NAOJ); The National Research Council (NRC) of Canada Herzberg Astronomy & Astrophysics; The University of California at Los Angeles (UCLA); The University of California at San Diego (UCSD) and The University of California at Santa Cruz (UCSC).

TMT Optics and Systems Engineering teams have reached another major milestone, with a successful “gate” review of the TMT optical Test INstruments System (TINS) preliminary design.   When TMT is built, all systems will be extensively tested and tuned during a technical verification phase, prior to be handed over to operations. The three mirror systems (M1, M2 & M3) will have to undergo a commissioning and test phase, and each of TMT’s 492 mirror segments forming M1 will need to be aligned after installation. These tests will be conducted with two custom-built systems placed above the primary mirror, the Prime Focus Camera (PFC) and the Global Metrology System (GMS), both major components of TINS.   Prime Focus Camera (PFC) Concept The PFC conceptual design was part of this review. PFC is a camera system that will be installed at the prime focus of the Primary Mirror (M1), at the top of the telescope structure, at the same location where the telescope laser guide star facility will be installed. PFC will be used as an imaging device during the Assembly, Integration and Verification (AIV) activities to assist with the alignment of the first M1 segments. PFC will support a series of control measurements. Its optical feedback will facilitate early pointing models to be made. It will also be used to confirm the tracking performance and initial calibration of the segments. The main optical requirement for PFC is to view a fraction of M1 segments, up to a 20-meter diameter. The PFC will consist of a CCD camera, corrector lenses, and a filter wheel containing neutral density filters, mounted on a 3-D positioning stage. Electronics and adapters will enable the system to be controlled via Ethernet. Following the installation of M1 segments, PFC will be removed to carry out the M2 installation. Global Metrology System (GMS) Design Overview The GMS is a permanent and flexible system mounted on the telescope that can be adapted to different metrology tasks. Based on laser trackers, GMS will assist in the alignment of the telescope optics during initial telescope assembly. GMS will serve to perform initial alignment when TMT engineers progressively build up the telescope optical system, following the telescope alignment plan.   GMS consists of three fixed laser trackers mounted in the elevation structure (see figure below), and one additional mobile laser tracker that will be used on the Nasmyth platform. Laser trackers will measure the 3-D position of Spherically Mounted Retroreflectors (SMRs) placed at key locations on the telescope structure, optics, and science instruments.   The TMT Optics and Systems Engineering teams have modeled the TMT laser tracker and SMR locations and estimated the accuracy of the measurement provided by the GMS, along with hazard analysis, risk assessments and possible mitigation means. All these studies were documented and reported during the TINS review.   Primary Mirror Alignment with GMS Primary Mirror Fixed Frame Alignment Primary Mirror Fixed Frame Alignment. During TMT initial optical alignment, the location of each M1 fixed frame is determined using 3 Spherically Mounted Retroreflectors (SMRs) located at the upper three corners of a mounted Metrology Frame, and visible to the laser trackers - Image credit: TMT International Observatory Each M1 segment will be supported by a fixed frame whose position will be measured by the GMS. Each fixed frame will be loaded with a mass simulator to model the deflection caused by the final segments and their support assemblies. In order to allow the SMRs to be visible above the segment dummy masses, SMRs will be mounted onto a subsidiary frame called the Metrology Frame, which will be seated on the fixed frames. The Metrology Frame has been designed to be light, stiff, and thermally stable, and is made of special low thermal expansion carbon fiber composite tubing. GMS will also measure the outer edge of the assembled M1 mirror by using SMRs mounted in machined pockets on the perimeter of M1.   When the facility is in operations, GMS will support measuring the relative alignment of TMT’s optical elements as part of periodic maintenance activities.   GMS Alignment of M2, M3, and Instruments GMS will also measure the positioning of the Secondary (M2) and Tertiary (M3) mirrors during installation, using SMRs mounted around their perimeters and aligned with the laser trackers. TMT Global Metrology System Devices TMT Global Metrology System Devices The Global Metrology System is a surveying system, built around commercial laser trackers, that will be used for a variety of alignment tasks in the observatory. The above image shows the mobile version of the laser tracker, which will be used on the Nasmyth platform to measure the position of the science instruments - Image credit: TMT International Observatory   The TMT science instruments and the Adaptive Optics Facility (NFIRAOS) will themselves be mounted onto the Nasmyth platforms. Their positioning will also require alignment using GMS. A mobile laser tracker, mounted on a tripod that can be moved through various locations around the telescope, will be specifically used for that purpose.           Software Design TINS will need to be fully integrated with the rest of TMT’s software and provide compliant interfaces to the: - Laser Tracker software, to allow measurement campaigns to be created and executed and the results to be saved for analysis, and the - Prime Focus Camera, to allow the camera to be positioned, and the camera images to be collected, displayed and stored. GMS will intelligently record and combine the positioning measurements obtained from multiple stations, and compare them to their ideal modelled locations. For that purpose, TMT has selected the Hexagon Metrology Group’s Spatial Analyzer (SA)[1], an industry standard measurement and modeling tool commonly used for spatial analysis. Alastair Heptonstall, TMT Senior Opto-Mechanical Engineer leading the TINS group, acknowledged that “the TINS development effort has enormously progressed over the last year. The TINS design team has now received full approval to proceed to final design of the optical test instruments system, which will allow engineers to demonstrate the alignment of TMT core systems and the phasing of TMT primary mirror segments.”