Faculty

Professor of Electrical Engineering Ayfur Ozgur Aydin has won the 2018 Okawa Foundation Research Grant. The Research Grant Presentation Ceremony will occur in San Francisco in September.

The mission of the Okawa Foundation is promotion and development in the field of Information and Communications Technology through awards and research grants as well as efforts to nurture researchers, engineers, and providers. It also seeks to promote diversity and ubiquitousness of human communication and thereby contribute to the peace and prosperity of humankind.

Please join us in congratulating Ayfer for this well-deserved award!

Read more about the Okawa Foundation: www.okawa-foundation.or.jp/en/outline/index.html

A paper by Emeritus Professor Thomas Kailath and co-authors is included in the top 10 notable papers from the last 50 years of papers published in the journal "Linear Algebra and its Application (LAA)." LAA is published by Elsevier and was the first journal devoted to linear algebra.

Along with Thomas Kailath (Electrical Engineering), three more Stanford faculty have papers included in the notable papers list. Including Richard W. Cottle (Management Science and Engineering), George B. Dantzig (Operations Research and Computer Science), and G.H. Golub (Computer Science).

Please join us in congratulating Thomas Kailath along with all of the authors on their extraordinary contributions!

All of the notable papers are free to access, and are hosted in the Elsevier Mathematics Open Archive. The 10 notable papers are:

Complementary pivot theory of mathematical programming, Volume 1, Issue 1, January 1968, Pages 103-125, Richard W. Cottle, George B. Dantzig

On the Eneström-Kakeya theorem and its sharpness, Volume 28, December 1979, Pages 5-16, N. Anderson, E.B. Saff, R.S. Varga

A new look at the Lanczos algorithm for solving symmetric systems of linear equations, Volume 29, February 1980, Pages 323-346, B.N. Parlett

A generalization of the Eckart-Young-Mirsky matrix approximation theorem, Volumes 88–89, April 1987, Pages 317-327, G.H. Golub, Alan Hoffman, G.W. Stewart

Linear complexity parallel algorithms for linear systems of equations with recursive structure, Volumes 88–89, April 1987, Pages 271-315, I. Gohberg, T. Kailath, I. Koltracht, P. Lancaster

Scalings of matrices which have prespecified row sums and column sums via optimization, Volumes 114–115, March–April 1989, Pages 737-764, Uriel G. Rothblum, Hans Schneider

Pencils of complex and real symmetric and skew matrices, Volume 147, March 1991, Pages 323-371, Robert C. Thompson

Riemannian geometry and matrix geometric means, Volume 413, Issues 2–3, 1 March 2006, Pages 594-618, Rajendra Bhatia, John Holbrook

A constructive version of the Boyle–Handelman theorem on the spectra of nonnegative matrices, Volume 436, Issue 6, 15 March 2012, Pages 1701-1709, Thomas J. Laffey

Perron–Frobenius theorem for nonnegative multilinear forms and extensions, Volume 438, Issue 2, 15 January 2013, Pages 738-749, S. Friedland, S. Gaubert, L. Han

Additional Links:

• Linear Algebra and its Applications Journal
• LAA News, "Celebrating the Golden Anniversary of Linear Algebra and its Applications," 2018.

Congratulations to emeritus professor Jim Gibbons! Recognized by Avenidas for his significant contributions in the social well-being of the community at large.

"[...T]he former Dean of the School of Engineering at Stanford, is known internationally for his important achievements in education and for his development of fabrication technologies that were foundational for the modern semiconductor industries in Silicon Valley and around the world. Less well known is the fact that his work has also contributed significantly to the social well-being of our community at large. Jim also served on no less than 13 boards in the Valley (among them Cisco, Raychem, SRI, Lockheed Martin, PARC, and more). In the educational field, he vastly expanded and improved the Stanford Instructional Television Network, which provided topnotch education via television to thousands of engineers at local companies. Again, this provided a crucial piece of "infrastructure" to the Valley, and was a forerunner of present internet courses.

His engagement with the Santa Clara Juvenile Hall in 1996 led him and his colleagues at SERA Learning to develop a successful program that teaches at-risk youth how to manage their anger and walk away from fights. SERA's "Skills for Managing Anger" course has since be used in 355 schools and juvenile justice applications across the country, including Columbine High School and NYC after 9 /11. It included new student centered teaching methods that Jim had developed for the Stanford Video program. Jim credits his wife Lynn who supported him in all his endeavors. He says: "She encouraged me to do things that would serve the needs of others." Avenidas is thrilled to celebrate Jim's amazing contributions and success."

The 2018 Lifetimes of Achievement honorees include Nancy Mueller, Dick Mansfield, Ellie Mansfield, Kristine Erving, John Erving, Christy Holloway and Jim Gibbons.

Excerpted from the Avenidas press release, "Avenidas Unveils Names of Community Contributors for the 2018 Avenidas Lifetime of Achievement Awards," February 12, 2018.

Congratulations to professor Gordon Wetzstein! He is recognized by the Society for Imaging Science and Technology (IS&T) as Electronic Imaging (EI) Scientist of the Year. His citation reads, "for pioneering contributions to electronic imaging in the areas of computational light field and near-eye display technologies."

The EI Scientist of the Year award is given annually at the EI Symposium to a member of the electronic imaging community who who has demonstrated excellence and commanded the respect of his/her peers by making significant and substantial contributions to the field of electronic imaging via research, publications, or service.

About the IS&T

Founded in 1947, the Society for Imaging Science and Technology (imaging.org) is a professional internationalorganization dedicated to keeping members and others apprised of the latest scientific and technological developments in the field of imaging through conferences, educational programs, publications, and its website.

IS&T encompasses all aspects of imaging science, with particular emphasis on digital printing, electronic imaging, color science, image preservation, photofinishing, pre-press technologies, hybrid imaging systems, and silver halide research.

Related links

• EI Scientist of the Year
• Stanford researchers develop technique to see objects hidden around corners, March 2018.
• Gordon Wetzstein awarded Sloan Research Fellowship, February 2018.

Today the Association for Computing Machinery (ACM) named Andrea Goldsmith the 2018-2019 Athena Lecturer for contributions to the theory and practice of adaptive wireless communications, and for the successful transfer of research to commercial technology.

Professor Goldsmith is the Stephen Harris Professor in the School of Engineering. Her research is focused on the design, analysis, and fundamental performance limits of wireless systems and networks, as well as the application of communications and signal processing to biology and neuroscience.

Andrea introduced innovative approaches to the design, analysis and fundamental performance limits of wireless systems and networks. Her efforts helped develop technologies used in long-term evolution (LTE) cellular devices as well as the Wi-Fi standards that are used in wireless local area networks. She participated in the launch of companies to commercialize her work, which has led to the adoption of her ideas throughout the communications industry.

Andrea also serves on Stanford's Budget Group, Academic Council Advisory Board, Faculty Senate, and Faculty Women's Forum Steering Committee. She previously served as Chair of Stanford's Faculty Senate and as a member of its Commissions on Graduate Education and on Undergraduate Education, as well as its Task Force on Women and Leadership.

"The anytime, anywhere computing era in which we now live owes a debt to innovators like Andrea Goldsmith who have helped lay the groundwork for the wireless infrastructure that makes mobile computing possible," said ACM President Vicki L. Hanson. "Her work has improved the transmission, reception and overall quality of wireless communications. Importantly, Goldsmith's career has exemplified the spirit of the ACM Athena Lecturer Award in the numerous ways she has mentored young women throughout her career. She has helped prepare promising young women PhD students and postdocs for faculty positions, and she has worked to develop actionable strategies to improve the climate, recruitment and retention of women in the high tech industry."

Please join us in congratulating Andrea for this well-deserved recognition!

About ACM
ACM, the Association for Computing Machinery, is the world's largest educational and scientific computing society, uniting computing educators, researchers and professionals to inspire dialogue, share resources and address the field's challenges. ACM strengthens the computing profession's collective voice through strong leadership, promotion of the highest standards, and recognition of technical excellence. ACM supports the professional growth of its members by providing opportunities for life-long learning, career development, and professional networking. 
Excerpted from The ACM press release.  

Related Links

• Stanford Professor Receives ACM Athena Lecturer Award for Contributions to Wireless Communications, ACM Press Release, April 2018.
• Goldsmith Awarded UC Berkeley Distinguished EECS Alumni Award, February 2018.
• EE and CS Departments Host the 2017 Rising Stars Workshop, March 2018
• Professor Andrea Goldsmith elected to the National Academy of Engineering, February 2017.
• Prof. Goldsmith receives the 2017 IEEE WICE Mentorship Award, October 2017

Professor John L. Hennessy and retired UC Berkeley professor David Patterson have been named recipients of the 2017 ACM A.M. Turing Award for pioneering a systematic, quantitative approach to the design and evaluation of computer architectures with enduring impact on the microprocessor industry. Hennessy and Patterson created a systematic and quantitative approach to designing faster, lower power, and reduced instruction set computer (RISC) microprocessors. Their approach led to lasting and repeatable principles that generations of architects have used for many projects in academia and industry. Today, 99% of the more than 16 billion microprocessors produced annually are RISC processors, and are found in nearly all smartphones, tablets, and the billions of embedded devices that comprise the Internet of Things (IoT).

John is the James F. and Mary Lynn Gibbons Professor of Computer Science and Electrical Engineering, and Shriram Family Director, Knight-Hennessy Scholars. He was dean of the School of Engineering (1996-2000), university provost (1999-2000), and Stanford University's 10th president (2006-2016).

The ACM Turing Award, often referred to as the "Nobel Prize of Computing," carries a $1 million prize, with financial support provided by Google, Inc. It is named for Alan M. Turing, the British mathematician who articulated the mathematical foundation and limits of computing. Hennessy and Patterson will formally receive the 2017 ACM A.M. Turing Award at the ACM's annual awards banquet being held this June in San Francisco.

"ACM initiated the Turing Award in 1966 to recognize contributions of lasting and major technical importance to the computing field," said ACM President Vicki L. Hanson. "The work of Hennessy and Patterson certainly exemplifies this standard. Their contributions to energy-efficient RISC-based processors have helped make possible the mobile and IoT revolutions. At the same time, their seminal textbook has advanced the pace of innovation across the industry over the past 25 years by influencing generations of engineers and computer designers."

Attesting to the impact of Hennessy and Patterson's work is the assessment of Bill Gates, principal founder of Microsoft Corporation, that their contributions "have proven to be fundamental to the very foundation upon which an entire industry flourished."

Please join us in congratulating John for this outstanding recognition of quantitative computer architectures and impact on the microprocessor industry.

Related News:

"Marty Hellman receives 2015 ACM A.M. Turing Award," March 2016.

ACM press release, "Pioneers of Modern Computer Architecture Receive ACM A.M. Turing Award," March 21, 2018. 

Stanford News, "Former Stanford President wins Turing Award for contributions to computing," March 22, 2018.

In November 2017, the EE and CS departments hosted the Rising Stars Workshop. We welcomed 70 women from around the world for two days of workshops, panels, and discussions aimed at helping them navigate an academic career.

Rising Stars – now in it's 6th year – was started at MIT with the sole intention of helping women interested in academic careers navigate the process.

At the welcome dinner, Provost Persis Drell encouraged the participants to "always remember that the diversity you bring to the conversation is of enormous value. It's not about them having accepted or allowed you into the room, it's that they desperately need you to be there."

Co-chairs of the event were professors Moses Charikar, Andrea Goldsmith and Fei-Fei Li. They were joined by more than 30 faculty, as well as industry leaders to organize and run the event. The participants were selected from nearly 400 applications.

For the young scholars, hearing from a range of panelists with a variety of backgrounds helped give them the tools and the mindset they need to succeed. Umashanthi Pavalanathan, a doctoral candidate in social computing and natural language processing at Georgia Tech, said that as an international student from Sri Lanka, hearing the experiences of faculty members with similar histories gave her confidence: "When I see role models, I get inspired." Adds Sara Mouradian, a doctoral candidate in quantum information processing at MIT: "When you go to conferences, I'm usually the only one or one of two women in any given room of 50 to 100 people, so it's been great to see all these women." Being here, she says, has been "mind-blowing."

Thanks to all of our participants and support for the 2017 Rising Stars event.

Excerpted from "'Rising Stars' workshop raises visibility for women in engineering," Stanford Engineering, March 14, 2018.

Rising Stars 2017 website.

A driverless car is making its way through a winding neighborhood street, about to make a sharp turn onto a road where a child’s ball has just rolled. Although no person in the car can see that ball, the car stops to avoid it. This is because the car is outfitted with extremely sensitive laser technology that reflects off nearby objects to see around corners.

“It sounds like magic but the idea of non-line-of-sight imaging is actually feasible,” said Gordon Wetzstein, assistant professor of electrical engineering and senior author of the paper describing this work, published March 5 in Nature.

Related Links

• Stanford researchers develop technique to see objects hidden around corners, Stanford News, March 2018.
• Gordon Wetzstein awarded Sloan Research Fellowship, February 2018.
• Juan and Gordon to present at Stanford's Great Teaching Showcase, December 2017.

Oyekunle Olukotun, Cadence Design Systems Professor of Electrical Engineering and Computer Science at Stanford University, has been selected to receive the IEEE Computer Society 2018 Harry H. Goode Award. 

Related Links

Krishna Shenoy and team have been researching the use of brain machine interfaces (BMI) to assist people with paralysis. Recently, one of the researchers changed the task, requiring physical movement from a change in thought. He realized that the BMI would allow study of the mental rehearsal that occurs before the physical expression.

Although there are some important caveats, the results could point the way toward a deeper understanding of what mental rehearsal is and, the researchers believe, to a future where brain-machine interfaces, usually thought of as prosthetics for people with paralysis, are also tools for understanding the brain.

"Mental rehearsal is tantalizing, but difficult to study," said Saurabh Vyas, a graduate student in bioengineering and the paper's lead author. That's because there's no easy way to peer into a person's brain as he imagines himself racing to a win or practicing a performance. "This is where we thought brain-machine interfaces could be that lens, because they give you the ability to see what the brain is doing even when they're not actually moving," he said.

"We can't prove the connection beyond a shadow of a doubt," Krishna said, but "this is a major step in understanding what mental rehearsal may well be in all of us." The next steps, he and Vyas said, are to figure out how mental rehearsal relates to practice with a brain-machine interface – and how mental preparation, the key ingredient in transferring that practice to physical movements, relates to movement.

Meanwhile, Krishna said, the results demonstrate the potential of an entirely new tool for studying the mind. "It's like building a new tool and using it for something," he said. "We used a brain-machine interface to probe and advance basic science, and that's just super exciting."

Additional Stanford authors are Nir Even-Chen, a graduate student in electrical engineering, Sergey Stavisky, a postdoctoral fellow in neurosurgery, Stephen Ryu, an adjunct professor of electrical engineering, and Paul Nuyujukian, an assistant professor of bioengineering and of neurosurgery and a member of Stanford Bio-X and the Stanford Neurosciences Institute.

Funding for the study came from the National Institutes of Health, the National Science Foundation, a Ric Weiland Stanford Graduate Fellowship, a Bio-X Bowes Fellowship, the ALS Association, the Defense Advanced Research Projects Agency, the Simons Foundation and the Howard Hughes Medical Institute.

Excerpted from Stanford News, "Mental rehearsal prepares our minds for real-world action, Stanford researchers find," February 16, 2018.

Related News:

Research by PhD candidate and team detects errors from Neural Activity, November 2017.

Krishna Shenoy's translation device; turning thought into movement, March 2017.

Brain-Sensing Tech Developed by Krishna Shenoy and Team, September 2016.

Krishna Shenoy receives Inaugural Professorship, February 2017.