Keynote Addresses - Join us Tuesday, Wednesday, and Thursday!


Tuesday, August 27
8:30 AM  - 10:00 AM | Atrium Ballroom AB

Gathering Momentum: The History and Impact of Metrology on High Consequence Engineering
Dr. Marcey Hoover, Director Quality Assurance, Sandia National Laboratories

Keynote Abstract:
The Department of Energy’s system of National Laboratories delivers products with the highest safety, security, and reliability consequences. The ability to assure quality in the high consequence products of the National Laboratories is heavily dependent on adhering to sound engineering principles, including having a robust approach to measurement assurance. This presentation will provide a historic overview of the National Laboratories quality assurance approach and explore the role that measurement assurance and metrology have played throughout the history of the labs. Through a series of specific examples drawn from Sandia National Laboratories, the role of metrology and partnerships with NCSLI and NIST will be discussed. Although the approaches to be presented are based on the high consequence engineering environment of Sandia National Laboratories, the ideas are applicable to any organization that depends on metrology to deliver with excellence.

Biography:
As Quality Assurance Director at Sandia National Laboratories, Dr. Marcey Hoover is responsible for designing and sustaining the quality assurance system and associated technical capabilities at one of the nation’s preeminent science and technology facilities. She and her team help to ensure that Sandia’s ongoing work on some of the world’s most challenging security issues is executed flawlessly, with safety, security, and efficiency built into the process.

In her current role, Marcey leads some of the foundational aspects of Sandia’s quality system, including the Labs-wide ISO certification, the Labs’ policy system, and government oversight organization interfaces. She is responsible for Sandia’s Primary Standards Lab, one of the nation’s leading metrology laboratories. Marcey’s center also provides key technical expertise in systems engineering, statistical sciences, and human systems to Sandia’s mission programs.

Marcey previously served as the Chief of Operations for Sandia’s Energy and Climate program. During her 24-year tenure at Sandia, Marcey managed organizations responsible for quality engineering on new product development programs, research and development of complexity science and advanced computational techniques, development and execution of national security testing and evaluation programs, and several executive office functions, including corporate-level strategic planning.

Active in both the American Statistical Association and the American Society for Quality (ASQ), Marcey served two terms as the elected ASQ Statistics Division Treasurer. In 2019, Marcey was recognized as a Distinguished Alumni of Purdue University and named a Women Worth Watching by the Profiles in Diversity Journal. She currently serves on both the Purdue Strategic Research Advisory Council and the Statistics Alumna Advisory Board, and as a mentor for Big Brothers Big Sisters of New Mexico.

Marcey received her Bachelor of Science degree in mathematics from Michigan State University, and her Master of Science and Doctor of Philosophy degrees in mathematical statistics from Purdue University.



Wednesday, August 28
8:30 AM - 10:00 AM | Atrium Ballroom AB

The Revised SI, Mass Metrology, and The Cost of Freedom

Patrick J. Abbott, Quantum Measurement Division, Physical Measurements Laboratory, National Institute of Standards and Technology (NIST)

Keynote Abstract:
Since May 20, 2019, the world has been operating under an International System of Units (SI) that is realized through fixed, fundamental constants of nature. The benefits of this revision of the SI are many, but most prominent is the creation of a fundamental system of measurements that is firmly anchored to invariant quantities of the natural world. As such, the units of measure of the SI can be realized anywhere in the universe if experiments that relate a unit of interest to the appropriate constant of nature are available. This is the freedom imparted to metrology because of the SI revision. Major changes to established order can create inconveniences, be they changes in families, governments, or measurement systems. These inconveniences are usually temporary characteristics of the transition to the new way of doing things, whatever it is, and can be viewed as part of the price of progress. The SI is facing a transition of this type with the unit of mass, which is now defined in terms of the Planck constant. Although all necessary conditions were met for the adoption of the Planck-kilogram, the small differences between measurements carried out in different countries is deemed at this time (2019) to be slightly larger than required to ensure the desired level of international agreement for the mass unit. The Consultative Committee for Mass and Related Quantities (CCM) has devised a transition plan for going forward from the former definition of mass, the International Prototype Kilogram (IPK) to the independent realization of the Planck-kilogram. This plan relies on a consensus value of the mass unit to be determined by the world’s realization experiments until the differences between measurements decreases to an acceptable level. I will discuss this transition process and the implications for dissemination of the mass unit from NIST for the next few years. The cost of freedom for independent realization may be inconvenient now but will be well worth it in the long run.

Biography:
Patrick Abbott earned B.S. and M.S. degrees in Physics from Indiana University of Pennsylvania and the Pennsylvania State University, respectively.He joined NIST in 1992 as a member of the Pressure and Vacuum Group where he was responsible for the dissemination of the unit of pressure in the range of 10-1 Pa to 10-7 Pa. He joined the Mass and Force Group in 2007 to work on the vacuum-to-air transfer of the Planck-constant-based kilogram that will be adopted into the SI in 2018. Patrick has been involved in providing mass metrology support to the NIST-4 Kibble balance that is used to realize the kilogram in the Revised SI. He currently serves as the Mass Calibration Project Leader.



Thursday, August 29 | Keynote Breakfast
7:30 AM - 8:30 AM | Atrium Ballroom | Everyone is invited!
8:30 AM - 10:00 AM | Atrium Ballroom AB

  

RPMs and kHz: How Radio Rocked the World
Get Ready to Rock!

Jason Hanley PhD, Vice President of Education and Visitor Engagement, Rock & Roll Hall of Fame
Joe Butler, Education Instructor, Rock & Roll Hall of Fame


Keynote Abstract:
Guillermo Marconi in 1895 generated vertically polarized radio waves capable of propagating or “skipping,” off layers of the atmosphere. His discovery proved radio signals could travel beyond the visible horizon. By the mid-20th century these radio waves would usher music and rock & roll beyond cultural, social, and generational horizons as well.

Technological revolutions that allowed programming to whiz through Earth’s atmosphere at about 1.08 billion km/h inspired music revolutions of their own. Thousands of Watts of alternating current and amplitude modulation (AM) sent harmonizing voices soaring from cities like Chicago, IL to the rural Delta South of the United States. Young children in this region, many of whom would grow up to be some of rock and roll’s biggest stars, clutched their quieted radios to their ears late at night and never left home without them. Every note and word they discerned across the low fidelity of AM band signals would ring in their heads for days, weeks, and months, inspiring them to create new forms of music that didn’t exist in their own backyard.

The most popular and powerful frequencies primarily carried sounds of country, classical, and folk music until a Northeast Ohio DJ, Alan Freed, began broadcasting rhythm and blues (R&B) under the colloquial moniker of “rock & roll” in 1951 on the frequency of 850 kHz at 5,000 W. Freed’s friend Leo Mintz had witnessed firsthand the throngs of teenagers rifling through crates of R&B records and encouraged Freed to spin the “Big Beat” sounds during his late-night show “The Moondog House.” This show, along with the 1952 Moondog Coronation Ball concert helped to earn Cleveland its reputation as the birthplace of rock and roll.

In the next decades, advances in receiver technologies allowed broadcasting via frequency modulation (FM) to become a renegade, “free form” of radio. These frequencies provided higher fidelity, stereo sounds, and the freedom for pioneering DJs, like Dusty Street, to rock the West Coast of the United States. Notably the first female DJ in that market, she made her mark with an incomparable knack for creating radio programming “that took you on wild and exciting musical adventures.” She persevered despite corporate agendas driven by profits and continues broadcasting her favorite rock & roll songs from the Sirius XM studio at the Rock & Roll Hall of Fame.

In this keynote we will explore how radiating waves from 10 kilometers to 10 millimeters long and at one time juiced by 500,000 Watts of power have pushed the sounds of rock and roll through the air and into people’s hearts – from the early influences of Jimmy Rodgers and Louis Jordon to the iconic rock sounds of Little Richard, Janis Joplin, and The Beatles.

Biography:
Jason Hanley holds a PhD in Musicology from Stony Brook University and has been with the Rock Hall since 2004. Before coming to the Rock Hall he worked in New York as a performing musician, songwriter, record label owner, scholar and author, his latest book, Music Lab, We Rock!: A Fun Family Guide for Exploring Rock Music History, was released in 2014. Music has always been a central focus of his life, from seeing Elvis Presley when he was only five, performing live at CBGBs in the early 1990s, and his current work at the Rock Hall. Hanley has spent time at the lectern in several schools teaching classes in music history, electronic music, and popular music studies at Hofstra, Cleveland State, Case Western and Stony Brook University.

Joe Butler has been with the Rock & Roll Hall of Fame for 3 years but, has cumulatively 12 years of experience as a museum educator. As an Education Instructor at the Rock Hall he presents over 100 onsite programs per year for K-12 field trips and public audiences. The rest of his time in museum education included presenting and developing programming for the Center of Science and Industry (COSI) in Columbus, OH and the Great Lakes Science Center in Cleveland, OH. Born and raised in Akron, OH, Joe as a proud Buckeye attended The Ohio State University earning a B.A. in Middle Childhood Education focusing on Math and Science. Joe being a life-long drummer also participated in the Athletic Band while at Ohio State, rocking out on the drum set courtside at Ohio State Basketball games. He continues his love for playing music and learning by recently picking up the bass guitar and playing regularly with the Rock & Roll Hall of Fame’s house band The Backbeats.




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