Categories
Health & Medicine Researcher news SMU In The News Student researchers Subfeature

Slate: Making the Perfect Sprinter More Perfect

How Usain Bolt could have run even faster.

Slate online magazine journalist Adam Willis covered the research of SMU biomechanics expert Peter Weyand and his colleagues Andrew Udofa and Laurence Ryan for a story about the world’s fastest sprinter, Usain Bolt, and whether he could possibly run even faster with different form.

The article, “Making the Perfect Sprinter More Perfect,” published Aug. 4, 2017.

Weyand, who leads the SMU Locomotor Performance Laboratory, is an expert on human locomotion and the mechanics of running. In his most recently published research, Weyand was part of a team that developed a concise approach to understanding the mechanics of human running. The research has immediate application for running performance, injury prevention, rehab and the individualized design of running shoes, orthotics and prostheses. Called the two-mass model, the work integrates classic physics and human anatomy to link the motion of individual runners to their patterns of force application on the ground — during jogging, sprinting and at all speeds in between.

His lab also reported in June that world champion sprinter Usain Bolt may have an asymmetrical running gait. While not noticeable to the naked eye, Bolt’s potential asymmetry emerged after the researchers dissected race video to assess his pattern of ground-force application — literally how hard and fast each foot hits the ground. To do so they measured the “impulse” for each foot.

Udofa presented the findings at the 35th International Conference on Biomechanics in Sport in Cologne, Germany. His presentation, “Ground Reaction Forces During Competitive Track Events: A Motion Based Assessment Method,” was delivered June 18.

The analysis thus far suggests that Bolt’s mechanics may vary between his left leg to his right. The existence of an unexpected and potentially significant asymmetry in the fastest human runner ever would help scientists better understand the basis of maximal running speeds. Running experts generally assume asymmetry impairs performance and slows runners down.

Udofa has said the observations raise the immediate scientific question of whether a lack of symmetry represents a personal mechanical optimization that makes Bolt the fastest sprinter ever or exists for reasons yet to be identified.

Weyand also has been widely interviewed in years past on the controversy surrounding double-amputee South African sprinter Oscar Pistorius. Weyand co-led a team of scientists who are experts in biomechanics and physiology in conducting experiments on Pistorius and the mechanics of his racing ability.

Weyand, who is Glenn Simmons Professor of Applied Physiology and professor of biomechanics in the Department of Applied Physiology & Wellness in SMU’s Annette Caldwell Simmons School of Education & Human Development, is director of the Locomotor Lab.

The researchers described the two-mass model earlier this year in the Journal of Experimental Biology in their article, “A general relationship links gait mechanics and running ground reaction forces.” It’s available at bitly, http://bit.ly/2jKUCSq.

Read the full story.

EXCERPT:

By Adam Willis
Slate

Usain Bolt is the only person to win both the 100 and 200 meters at three Olympic games. He is also the only person to do this at two Olympic games. Bolt has broken five individual outdoor track and field world records, three of them his own. He has run three of the five fastest 100-meter races and four of the six fastest 200-meter races in history. As Bolt gets set for the World Athletics Championships in London, the final meet of his beyond-illustrious career, we should be grateful for all the memorable moments the world’s fastest man has given us. We should also be ingrates and ask: Could he have run faster?

Bolt has an uncanny knack for making the incredibly difficult look easy—like Muhammad Ali coming off the ropes, like Westley fencing with his left hand, like James Joyce writing Ulysses from Paris. It’s only natural to wonder, then, if he could have done more. His midrace celebrations, his apparent aversion for practice and affinity for parties, his less than sensible diet—he reportedly ate 1,000 Chicken McNuggets in 10 days during the Beijing Olympics—all suggest history’s greatest sprinter might’ve had a little bit more in the tank.

After Bolt breezed to a 9.69 world record in the 100 meters at the 2008 Olympics, jogging and chest thumping across the finish line just days before his 22nd birthday, his coach Glen Mills made headlines with his claim that Bolt would have hit 9.52, at worst, if he had just run through the line. Scientists took on the task of projecting the time that might have been, with most concluding that 9.52 was, at best, a slight exaggeration. Bolt, though, made that claim look less sensational when he tore through his own world records at the world championships in Berlin a year later, posting 9.58 in the 100 and 19.19 in the 200. Still, Bolt would never reach the 9.52 that Mills estimated, nor, for that matter, the 9.4 that he himself predicted. He would never best those world records that he set in Berlin, when he was not yet 23 years old.

“We haven’t seen the 2009 Bolt since 2009,” says Peter Weyand, the director of the Locomotor Performance Laboratory at Southern Methodist University and a leading expert on the science of sprinting. When I asked Weyand about Bolt’s early peak, he told me that, although 22 or 23 is not an unusual age for a sprinter to top out, he would have predicted more after Bolt’s 2009 performances.

While recent research from Weyand’s lab concluded that Bolt’s stride is abnormally asymmetric, Weyand says it’s unlikely this asymmetry held Bolt back in any way. He does point, however, to several aspects of Bolt’s form that are considered unorthodox and potentially suboptimal.

Read the full story.

Categories
Earth & Climate Energy & Matter Researcher news SMU In The News Subfeature

Dallas Innovates: SMU, UTA Scientists To Help Unlock Mystery of Neutrinos

A massive particle detector a mile underground is the key to unlocking the secrets of a beam of neutrinos that will be shot beneath the Earth from Chicago to South Dakota.

Reporter Lance Murray with Dallas Innovates reported on the research of biochemistry professors Thomas E. Coan in the SMU Department of Physics.

Coan is one of about 1,000 scientists around the world collaborating on DUNE — a massive particle detector being built a mile underground in South Dakota to unlock the mysteries of neutrino particles.

The research is funded by the by the U.S. Department of Energy’s Office of Science in conjunction with CERN and international partners from 30 countries.

SMU is one of more than 100 institutions from around the world building hardware for the massive international experiment that may change our understanding of the universe. Construction will take years and scientists expect to begin taking data in the middle of the next decade, said Coan.

The Long-Baseline Neutrino Facility (LBNF) will house the international Deep Underground Neutrino Experiment. When complete, LBNF/DUNE will be the largest experiment ever built in the United States to study the properties of the mysterious particles called neutrinos.

The Dallas Innovates article, “SMU, UTA Scientists To Help Unlock Mystery of Neutrinos,” published July 28, 2017.

Read the full story.

EXCERPT:

By Lance Murray
Dallas Innovates

Construction of a huge particle detector in South Dakota could lead to a change in how we understand the universe, and scientists from the University of Texas at Arlington and Southern Methodist University in Dallas will play roles in helping to unlock the mystery of neutrinos.

Ground was broken a mile underground recently at the Sanford Underground Research Facility at the Homestake Gold Mine in Lead, South Dakota for the Long-Baseline Neutrino Facility (LBNF) that will house the Deep Underground Neutrino Experiment (DUNE).

SMU physicist Thomas E. Coan, and UTA Physics professors Jonathan Asaadi and Jaehoon Yu will be among scientists from more than 100 institutions around the world who will be involved in the experiment.

DUNE will be constructed and operated at the mine site by a group of about 1,000 scientists and engineers from 30 nations.

The Homestake Mine was the location where neutrinos were discovered by Raymond Davis Jr. in 1962. It was the the largest and deepest gold mine in North America until its closure in 2002.

LBNF/DUNE will be the biggest experiment ever built in the U.S. to study the properties of neutrinos, one of the fundamental particles that make up the universe.

“DUNE is designed to investigate a broad swath of the properties of neutrinos, one of the universe’s most abundant but still mysterious electrically neutral particles,” Coan said in the release.

These puzzling particles are similar to electrons, but they have one huge difference — they don’t carry an electrical charge. Neutrinos come in three types: the electron neutrino, the muon, and the tau.

What is the experiment’s goal? Coan said it seeks to understand strange phenomena such as neutrinos changing identities in mid-flight — known as “oscillation” — as well as the behavioral differences between a neutrino and its anti-neutrino sibling.

“A crisp understanding of neutrinos holds promise for understanding why any matter survived annihilation with antimatter from the Big Bang to form the people, planets, and stars we see today,” Coan said in the release. “DUNE is also able to probe whether or not the humble proton, found in all atoms of the universe, is actually unstable and ultimately destined to eventually decay away. It even has sensitivity to understanding how stars explode into supernovae by studying the neutrinos that stream out from them during the explosion.”

Coan also is involved in another massive particle detector in northern Minnesota knows as NOvA, where he is a principal investigator.

Read the full story.

Categories
Culture, Society & Family Economics & Statistics Researcher news SMU In The News Subfeature

Dallas Fed, SMU and consortium to establish new Federal Statistical Research Data Center

The center will advance scientific knowledge, improve data quality and inform policy in fields ranging from the social, behavioral and economic sciences to health professions, urban planning and engineering.

A consortium of institutions led by the Federal Reserve Bank of Dallas and the University of Texas at Dallas will partner with the U.S. Census Bureau to establish the Dallas-Fort Worth Federal Statistical Research Data Center.

The DFW center is the result of an extensive grant application process involving contributions from each consortium member and a review by the National Science Foundation and the U.S. Census Bureau. One of several planned Federal Statistical Research Data Center locations across the country, the center will be housed at the Dallas Fed and will provide approved researchers with secure access to restricted micro-level data.

“The establishment of this center is the culmination of two years’ worth of effort on the part of the Bank and consortium to bring this important new research facility to North Texas,” said Dallas Fed President Rob Kaplan. “Our role in this project aligns well with the Bank’s strategic priorities of serving as a thought leader in policy-related research and being a leading citizen in the communities we serve.”

The center will advance scientific knowledge, improve data quality and inform policy in fields spanning the social, behavioral and economic sciences and the health professions, and extending to urban planning, and engineering. The cutting-edge research opportunities afforded by the center will raise the profile of participating institutions and assist in attracting and retaining top research talent to the region.

“This is a very positive demonstration of how the major universities and institutions in the DFW area, along with West Texas, can work together to both increase quality research as well as strengthen the ties between consortium members,” said Kurt Beron, professor of economics at UT Dallas, who played a leading role in the grant application process and will help coordinate the consortium.

In addition to the Dallas Fed and UT Dallas, the consortium includes UT Arlington, UT Southwestern Medical Center, Southern Methodist University, Texas Tech University, University of North Texas, Texas Christian University and the Dallas-Fort Worth Hospital Council Foundation.

The DFW center is expected to open in early 2018. Wenhua Di, senior research economist at the Dallas Fed, will serve as executive director of the center.

“There is significant demand in the region for this center,” said Di. “Since researchers need to be physically present to access the data, housing the center at the Dallas Fed will provide excellent security, easy accessibility and collaboration opportunities to a large research community.”

The new data center will encourage greater use of federal statistical data among faculty, researchers and graduate students in the many diverse research institutions in the DFW area, including traditional universities and health institutions. It will also provide access to West Texas and the Panhandle, as well as parts of Oklahoma. In addition, two major airports in the area provide convenient gateways for researchers in the region as well as nationally.

The research data center program is administered by the Census Bureau’s Center for Economic Studies. More information about the FSRDCs is available at https://www.census.gov/fsrdc. — Federal Reserve Bank of Dallas

Categories
Culture, Society & Family Learning & Education Researcher news SMU In The News Subfeature

D CEO: Why You Need to Know Suku Nair

The director of the new AT&T Center for Virtualization at SMU will drive crucial technical research and help create a knowledgeable North Texas employee base.

D Magazine’s D CEO profiled longtime SMU faculty member Suku Nair, a professor in the SMU Department of Computer Science and Engineering in the Bobby B. Lyle School of Engineering.

Nair has been named director of the AT&T Center for Virtualization at SMU. He is an internationally recognized authority on cyber security and reliable computing and communication, and founding director of the HACNet (High Assurance Computing and Networking) Lab at SMU.

AT&T and SMU in December 2016 announced the two would collaborate in a unique new research center that would deliver solutions to critical industry needs, educate the next generation of virtualized network technology experts and support Dallas’ emergence as a global information technology hub.

A $2.5 million contribution from AT&T to SMU endows the AT&T Center for Virtualization and funds its research to support the fast, reliable cloud-based telecommunications necessary for global connectivity.

Nair said at the time of the announcement that “AT&T is a leader in providing connectivity for a wide variety of resources, both on and off the cloud, requiring deployment of hundreds of thousands of complex, expensive routers. The cost comes down and the system becomes more agile and efficient if the routers can be simplified by putting the intelligence that makes them work on the cloud.”

Through the AT&T Center for Virtualization, students will leave SMU not just with textbook knowledge, but with knowledge earned through hands-on research carried out in partnership with industry. Equally important, the center will be a critical resource in Dallas as the city continues to evolve as a global information technology hub.

Read the full story.

EXCERPT:

By Danielle Abril
D CEO

Because he will spearhead technical research that could become essential to doing business in the future. He also will help provide North Texas companies with a technologically well-versed talent pool.

As director of the new AT&T Center for Virtualization at Southern Methodist University, Nair, 53, will be at the center of understanding some of tomorrow’s biggest technology challenges. And, with a $2.5 million endowment from AT&T, his center’s research will help companies across industries migrate from hardware and launch software- and cloud-based systems to increase efficiency, accessibility, and reliability.

Nair plans to work side by side at the center with companies like AT&T, which aims to commission research as it seeks out solutions to create stronger global connectivity. If all goes as expected at the new venture, Dallas could emerge as a hub for information technology, heavy with talent, companies, and research.

“This is going to be a forum for universities, industries, and government to come and freely exchange ideas,” Nair says, adding that “everyone” is dealing now with virtualization issues in business. “We have the track record, and we are in the right place and the right time.”

Nair has been working at SMU since 1990, when he joined the university as a professor in computer science and engineering. The Illinois transplant quickly recognized Dallas-Fort Worth’s robust business environment and knew he wanted to play an integral role in research for some of the largest local firms.

The Telecom Corridor in Richardson was alive and well back then, and Nair was able to land his first research contract with Alcatel in 1993. He also helped SMU launch its cybersecurity program, which has since received nearly $10 million in endowments and funding. Over the years Nair has generated several million dollars in research for companies. “Sometimes they’ll have some technology problems they want to solve,” says Nair, who brings his SMU students into the process of researching possible solutions. “It’s a very cost-effective means of doing research, and it trains students to be hired.”

The AT&T research center will be located in the Gerald J. Ford Research Building, which will be built at SMU with help of a $15 million endowment from Gerald J. Ford, Kelli O. Ford, and The Gerald J. Ford Family Foundation. The timing and location for the building, which will highlight the center on the ground floor, is still being determined. The center currently operates out of temporary space at SMU’s east campus, across from U.S. Highway 75. Nair expects the center to attract companies from the region, state, and beyond, as it delves into a topic with broad appeal and an increasingly more powerful impact.

Read the full story.

Categories
Health & Medicine Researcher news SMU In The News Subfeature

New York Times: Blade Runner Tests Limits of Prosthetics, Years After Oscar Pistorius

Track-and-field rules regarding athletes with prosthetic limbs remain gray, even nonexistent.

The New York Times reporter Filip Bondy interviewed SMU biomechanics expert Peter Weyand of the SMU Locomotor Laboratory, for a story about Hunter Woodhall, an 18-year-old athlete with prosthetic limbs competing against top scholastic stars in the United States.

Weyand, who is Glenn Simmons Professor of Applied Physiology and professor of biomechanics in the Department of Applied Physiology and Wellness in SMU’s Annette Caldwell Simmons School of Education and Human Development, is director of the Locomotor Lab.

An expert on human locomotion and the mechanics of running, Weyand has been widely interviewed about the controversy surrounding double-amputee South African sprinter Oscar Pistorius. Controversy has swirled around the sprinter over whether his light-weight, carbon-fiber prosthetic “Cheetah” legs give him a competitive advantage.

Weyand helped lead a team of scientists who are experts in biomechanics and physiology in conducting experiments on Pistorius and the mechanics of his racing ability.

For his most recently published research, Weyand was part of a team that developed a concise approach to understanding the mechanics of human running. The research has immediate application for running performance, injury prevention, rehab and the individualized design of running shoes, orthotics and prostheses. The work integrates classic physics and human anatomy to link the motion of individual runners to their patterns of force application on the ground — during jogging, sprinting and at all speeds in between.

The New York Times article, “Blade Runner Tests Limits of Prosthetics, Years After Oscar Pistorius,” published March 13, 2017.

Read the full story.

EXCERPT:

By Filip Bondy
The New York Times

A decade after Oscar Pistorius caused track-and-field officials to re-examine their rules regarding the use of prosthetic limbs at the Olympics, a high school amputee is running in open competition on similar carbon-fiber blades. And once again, guidelines are gray, even nonexistent.

The athlete, Hunter Woodhall, 18, from Syracuse, Utah, is at the Armory track in Manhattan to run in an invitational, 400-meter heat on Saturday at the New Balance Nationals Indoor, competing against the top scholastic stars in the country.

One of the youngest competitors at the Rio Paralympics, Woodhall won silver in the 200-meter competition at 21.12 seconds and bronze in the 400 with a personal-best 46.70. He also appeared to capture gold while anchoring the 4×100 relay, but the United States team was disqualified over an exchange violation on an earlier leg.

Amid these successes, background grumbling appears to have increased in connection with his eligibility for open competitions.

Woodhall has such a winsome personality, it is impossible to imagine anyone complaining to his face about anything. The meet directors are thrilled to have him participate. But there are no hard-and-fast rules regarding the eligibility of bladed runners at scholastic or collegiate levels, and the scientific debate has never been fully settled about whether the prosthetics offer a competitor some unfair advantage.

“When something different comes along, people want an answer,” Woodall said. He added that “staying away’’ from the whole debate might be the best alternative.

“Fighting this war is not going to go anywhere,” he said. “At the end of the day, I’m not a scientist, they’re not a scientist, we’re not going to come to a consensus. I just put in the work.”

A decade ago, long before he was convicted in the murder of his girlfriend, Reeva Steenkamp, Pistorius was effectively banned from open competition by the International Association of Athletics Federations. The group in 2007 prohibited any device that “incorporates springs, wheels or any other element that provides a user with an advantage.”

After further testing at Sport University Cologne, in Germany, on behalf of the I.A.A.F., a report concluded that Pistorius’s legs were using 25 percent less energy than those of “able-bodied” runners. He was declared ineligible for the 2008 Olympics in Beijing.

That ban was overturned by the Court of Arbitration for Sport in Lausanne, Switzerland, after further testing at Rice University resulted in a paper for the Journal of Applied Physiology contending that Pistorius was “mechanically dissimilar” to competitors racing on legs, moving his body differently.

Even the scientists involved in the Rice study could not come to complete agreement, however. According to a report in Scientific American, Peter Weyand, a physiologist at Southern Methodist University, believed Pistorius had a mechanical edge. A biomechanics expert, Rodger Kram from the University of Colorado, contended that Pistorius’s artificial limbs created as many problems as advantages.

The court ruled that the testing in Cologne had not factored in the disadvantages of Pistorius’s motion around a curve, or his problems at the start of a race. (These are also the elements of every competition that present the greatest challenges to Woodhall.) Pistorius was eventually selected to participate for South Africa in the 2012 Olympics in London.

Read the full story.