Freeform Optics explores the evolving impact of freeform optical surfaces on optical systems for both imaging and illumination. New fabrication techniques that create optical surfaces that are not surfaces of revolution open an expansive new space for optical systems. Particularly enabled systems include illumination systems, head-worn displays and mid- and long-wave pervasive surveillance systems. But optical testing methods for these new surfaces are lacking, and the theory and implementation of an aberration theory as a basis for optical design of these surfaces was only unraveled in 2012. The scope features work on the optical design of imaging systems with freeform surfaces, evolving methods for surface representation for illumination system optimization and a perspective on the new challenges these surface present to optical testing.
With the ever expanding successes from the introduction of freeform surfaces into both imaging and nonimaging (illumination) optical systems, there is innovative work being done in both academia and industry in all areas of optical system evolution including,
- Optical design
- Optical system simulation
- Surface representation
- Optical system assembly
Aaron Bauer, University of Rochester, United States
Analyzing the Aberration Fields of a Three-mirror Telescope and Correcting them using Freeform Zernike Surfaces, Invited
Gernot Berger, Westfaelische Wilhelms-Universitaet, Germany
Non-contact metrology of aspheres and freeforms based on a scanning point interferometer, Invited
Matthew Currie, PowerPhotonic Ltd, United Kingdom
Design, Fabrication and Simulation of Freeform Silica Micro-Optics, Invited
Jay Daniel, L-3 Integrated Optical Systems-Tinsley, United States
Freeform Aspheres in an Augmented Reality Application, Invited
Chris Evans, Univ of North Carolina at Charlotte, United States
Freeform Optical Metrology Standards, Invited
Ulrike Fuchs, Asphericon GmbH, Germany
Fabrication and Metrology Challenges for Freeform Commercial Imaging System Development , Invited
Dae Wook Kim, University of Arizona, United States
Fabrication and dynamic deflectometry testing methods for freeform and deformable optics, Invited
Rongguang Liang, University of Arizona, United States
Freeform Optics for Imaging and Non-Imaging, Invited
Christoph Menke, Carl Zeiss AG, Germany
Optical Design with Orthogonal Freeform Representatives , Invited
Bryan Stone, Synopsys, Inc, United States
Low-order Aberration Coefficients Applied to Design of Telescopes with Freeform Surfaces, Invited
Yongtian Wang, Beijing Institute of Technology, China
Freeform for Virtual and Augmented Reality, Invited
Jessica DeGroote Nelson, Optimax Systems Inc., USA
John Rogers, Synopsys, Inc., USA
Fabian Duerr, Vrije Universiteit Brussel, Belgium
Matt Davies, Univ. of North Carolina at Charlotte, USA
Joseph Howard, NASA Goddard Space Flight Center, USA
John Koshel, University of Arizona, USA
Kate Medicus, Optimax Systems Inc., USA
Juan Carlos Miñano, Universidad Politécnica de Madrid, Spain
Julius Muschaweck, Arnold & Richter Cine Technik GmbH & Co., Germany
Jannick Rolland, University of Rochester, USA
Short Course - Meaningful Scratch and Dig Specifications
9 July, 14:00-18:00
Dave Aikens, the Presider and found of Savvy Optics Corp. will present this course.
Opening Plenary Session
10 July, 8:00-10:00
Closing the Wage Gap - AAUW Work Smart Salary Negotiation
- Patrick McCarthy Giant Magellan Telescope, USA
- Joshua Smith California State University Fullerton, USA
- Jannick Rolland University of Rochester, USA
10 July, 12:30 – 14:00
Join us for an interactive workshop focused on closing the wage gap and providing attendees resources designed to help negotiate for a new job, raise, or promotion. Attendees will gain confidence in negotiation style through facilitated discussion and role-play.
- How to identify and articulate your personal value
- How to develop an arsenal of persuasive responses and other negotiation strategies, including how to get a raise or promotion
- How to conduct objective market research to benchmark a target salary and benefits
- About the wage gap, including its long-term consequences
Why is negotiation so important? AAUW’s research on the gender pay gap shows that, one year out of college
, women are already paid significantly less than their male counterparts. Women who work full time take home 80 cents
for every dollar a full-time male worker is paid. And over a lifetime, those lost potential earnings add up.
10 July, 18:00-20:00
Join your fellow attendees for a Western Style Barb-B-Q. Enjoy delectable fare while networking. The BBQ is open to committee/presenting author/student and full conference attendees. Conference attendees may purchase extra tickets for their guest.
Creating Effective Conference Posters Lunch & Learn
11 July,12:30 – 14:00
Join us for an interactive lunch & learn program focused on creating effective conference posters. Jean-luc Dumont will provide relevant examples and real life experiences to enhance your communication and conference poster development. You will leave this workshop with an understand of the best practices in poster creation and presentation. Lunch will be provided.
Joint Poster Session
11 July, 18:00-19:30
Posters are an integral part of the technical program and offer a unique networking opportunity, where presenters can discuss their results one-to-one with interested parties. Each author is provided with a board on which to display the summary and results of his or her paper.
IODC Illumination and Lens Design Problems Presentation
12 July, 18:00-20:00
Join the IODC community for a guaranteed highlight of the conference: the illumination and lens design contest presentations. As usual, significant work has gone into developing and scoring the submissions, as well as all of the hard work put in by solution submitters.
Giant Magellan Telescope, USA
Giant Magellan Telescope, Optics and Science
The world’s next great astronomical observatory – The Giant Magellan Telescope – will be used to explore the early Universe and to search for life on other planets. I will describe the scientific mission and the engineering challenges involved in its design and construction.
Bio: Patrick McCarthy is the Interim President of the Giant Magellan Telescope Project. He received his Ph. D., in Astronomy from U. C. Berkeley in 1988. He went to the Carnegie Observatories first as a Carnegie Fellow and then as a Hubble Fellow in 1991. In 1993 he joined the scientific staff at Carnegie. He is known for his work on galaxies in the distant universe and, in particular, for his study of distant low frequency cosmic radio sources: sign posts to massive galaxies undergoing rapid accretion on to super massive black holes. In the late 1990s, McCarthy and his colleagues identified a new population of galaxies with colors indicative of very early star formation. Study of these faint red galaxies is now one of the most active areas of research in astrophysics.
McCarthy has been active in scientific and management oversight of large science projects and organizations. He has chaired numerous panels for NASA and the NSF providing independent oversight of the Hubble Space, Spitzer Space Telescope, and large telescopes on the ground. McCarthy led the Giant Magellan Telescope (GMT) Science Working Group that wrote the scientific case for the telescope project and defined the scientific and technical requirements for the facility.
Today, he leads the team of scientists and engineers building the Giant Magellan Telescope (GMT), an enormous instrument comprised of seven primary mirror segments—the seven largest mirrors ever made—that will stretch to more than 80 feet across once complete. The GMT will explore the cosmos to observe the first stars in the universe, offering images 10 times sharper than those coming from the Hubble Space Telescope. Since 2008, he has served as the head of the non-profit corporation, GMTO, that is charged with carrying out the development, construction and operation of the telescope and related facilities. My day-to-day responsibilities include ensuring that the telescope and its instruments will be able to address the key questions at the forefront of astrophysics in 2020 and beyond.
California State University Fullerton, USA
Using Optics and Precision Metrology in to Measure Black Hole Mergers from Across the Universe with LIGO
On September 14, 2015 the two detectors of the Laser Interferometer Gravitational Wave Observatory (LIGO) detected gravitational waves from the merger of a binary system of black holes. This discovery could not have been made without a century of advances in optical technology and precision metrology. I will give an overview of gravitational waves detected by LIGO to date and describe the optics involved and current optical challenges. I will end with prospects for future gravitational-wave observations made with even more advanced optics.
Bio: Joshua Smith directs the Gravitational-Wave Physics and Astronomy Center (GWPAC) and is an associate professor of physics at California State University, Fullerton. Currently he is active in gravitational research, astronomy education research, and teaching physics and astronomy. His research is focused on detecting gravitational waves from astronomical sources using the Laser Interferometer Gravitational-wave Observatory (LIGO) in collaboration with colleagues in GWPAC and in the international LIGO Scientific Collaboration.
University of Rochester, USA
Freeform Optics from Design to Manufacture and its Envisioned Impact on Technology to Enable the Science of Tomorrow
All-reflective optical solutions have long hold their place in optical system design from small scale optics as in microscopes to large scale optics as in telescopes. Yet reflective solutions have suffered from obscuration or the need to restrain surfaces to be off-axis conics or aspherics. The ability to recently fabricate freeform surfaces opens up new spaces for optical design, driven by applications spanning demands in mobility, larger fields of view, apertures, light weight and compactness. I will present success stories designing and prototyping designs with freeform surfaces and highlight pathways and challenges associated with their emergence.
Bio: Jannick Rolland is the Brian J. Thompson Professor of Optical Engineering at the University of Rochester and she directs the NSF I/UCRC Center for Freeform Optics (CeFO).
Rolland joined the University of Rochester in 2009 after advancing her career from Assistant to Full Professor at CREOL, the College of Optics and Photonics at the University of Central Florida. Together with colleagues at the University of Rochester and partners at the University of North Carolina at Charlotte, she launched in 2013 the Center for Freeform Optics (CeFO) as an international consortium aimed at advancing the science and engineering of freeform optics. Rolland earned an optical engineering diploma from the Institut D'Optique Théorique et Appliquée, France, and a PhD in Optical Science from the College of Optical Sciences at the University of Arizona. She is a Fellow of OSA, SPIE, and NYSTAR. She is the recipient of the 2014 OSA David Richardson Medal. She is known for her innovations since the 90s in head-worn displays, and more recently her innovations in 3D microscopy and telescope designs.