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U.S. Senate confirms Schmidt to lead operational testing and evaluation for the Department of Defense – Vanderbilt University News

Douglas Schmidt, Cornelius Vanderbilt Professor of Computer Science, has been confirmed to become Director of Operational Test and Evaluation for the Department of Defense following a full vote by the U.S. Senate on Feb. 29, 2024.

In testimony before the Senate Armed Services Committee on Jan. 23, Schmidt said if confirmed that hes ready to fulfill his duties.

Im committed to fostering robust collaborations with our research and engineering community, acquisition programs, armed services and international partners, he told the committee. Im eager to fulfill my responsibilities by collaborating closely with key stakeholders, including Congress, the department, the services and industry partners.

An internationally renowned computer scientist, Schmidts professional involvement with national security spans four decades, marked by extensive work in researching, developing and testing military systems.

Professor Schmidts distinguished career of bold discovery and innovation at Vanderbilt will serve him and our nation well in his new role, Chancellor Daniel Diermeier said. His work, and his collaborations across sectors in forums like our Summit on Modern Conflict, make him especially qualified to help shift the nations defenses forward toward a greater focus on cyber conflict and digital innovation. I congratulate Professor Schmidt on this great honor and wish him every success in serving our country.

Schmidt has particular expertise in the integration of software systems with hardware, mobile systems and other physical components. He is a senior researcher at the Vanderbilt Institute for Software Integrated Systems and a visiting scientist at the Software Engineering Institute at Carnegie Mellon University.

In his written testimony to the Senate Armed Services Committee, Schmidt emphasized the pressing need to shift from pursuing innovations in hardware-centric systems to focusing on a landscape defined by software, data and complex algorithms.

Professor Schmidt is an accomplished computer scientist who possesses a successful record of translating research innovation into real-world results, said Krishnendu Roy, Bruce and Bridgitt Evans Dean of the School of Engineering and University Distinguished Professor. He has had a distinguished career in academia and government, especially in the defense sector. His selection for the role of DOT&E is an inspired choice and is another example of how Vanderbilt researchers are making a lasting societal impact for the United States and beyond. I congratulate him on this well-deserved honor.

Schmidts experience includes evaluating software product lines for mission computing systems in military fighters and leading mission-critical technology projects for the Navy and Air Force as a program manager at the Defense Advanced Research Projects Agency. From 2010 to 2014, he served as vice chair of a study on cyber situational awareness for Air Force mission operations as a member of the Air Force Scientific Advisory Board.

Most recently, Schmidt led research and development efforts at Vanderbilt University and CMU/SEI focused on responsible application of generative augmented intelligence in automated programming and testing of defense acquisition systems.

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North Park University Introduces New Bachelor of Arts in Applied Computer Science for Fall 2024 – PR Newswire

CHICAGO, March 6, 2024 /PRNewswire/ -- North Park University announced today that it is adding a new major in applied computer science (BA) to provide students with expertise in high-growth areas where employers are searching for talent.

The hybrid program will be taught both on North Park's campus and online via a partnership with the Lower Cost Models Consortium (LCMC) and Rize Education. The LCMC is a strategic partnership of private colleges and universities nationwide, collaborating with Rize Education to provide access to a cutting-edge curriculum that prepares students for successful careers.

The involved parties directly collaborated with Google to build computer science courses that will develop graduates to fill essential and understaffed roles across tech industries. With employment in the field expected to grow at roughly 22% over the next decade (nearly three times the national average), graduates will qualify for increasingly valuable jobs in Illinois and nationwide. Project-based and portfolio-building classes will help students produce impressive resumes before graduation and hone skills that hiring managers demand.

North Park Provost Michael Carr said, "Our faculty and academic leadership have worked creatively to develop this program, which will provide our students with opportunities to acquire skills for the growing field. Combined with our liberal arts core, this new major will prepare students for lives of significance and service."

ABOUT THE LOWER COST MODELS CONSORTIUM (LCMC) Formed in 2015, the LCMC is a national consortium of over 130 fully accredited nonprofit colleges and universities. LCMC members are committed to collaborating to address the challenges of increasing costs in higher education by implementing innovative programs and reducing institutional expenses for these programs to pass savings along to students. In this way, the LCMC hopes to develop new models of higher education that benefit students while contributing to the sustainability of accredited, nonprofit, four-year institutions.

ABOUT NORTH PARK UNIVERSITY North Park Universityis city-centered, intercultural, and emerging as the model for Christian higher education in 21st century America.

SOURCE North Park University

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UTSA joins federal consortium to advance AI safety – The University of Texas at San Antonio

MARCH 6, 2024 UTSA has joined the U.S. Artificial Intelligence Safety Institute Consortium (AISIC), an organization established by the U.S. Department of Commerces National Institute of Standards and Technology (NIST), to bring together government, university and industry researchers, AI creators and users, and community groups to support the development and deployment of trustworthy and safe AI.

UTSAs inclusion in the national consortium is a testament to its expertise in artificial intelligence, data science, computing and cybersecurity as well as its robust educational programs to develop career-ready Roadrunners who are prepared to succeed in the growing artificial intelligence workforce.

We are proud to collaborate with this consortium to help lead the way in these cutting-edge fields and to continue to expand the universitys collective expertise for the benefit of the institution and our UTSA students, said Heather Shipley, interim provost and executive vice president for academic affairs.

The AISIC includes more than 200 member organizations and institutions that are on the frontlines of researching, developing and/or leveraging AI systems to positively transform society. These entities represent the nations largest companies and innovative startups, creators of the worlds most advanced AI systems and hardware and representatives from professions with deep engagement in AIs use today.

The universitys combined assets, particularly within the School of Data Science and the National Security Collaboration Center, position UTSA to play a crucial role in advancing the mission of the consortium, said Jianwei Niu, interim executive director of the School of Data Science and interim dean of University College.

Niu noted that David Mongeau, former founding director of the SDS, was instrumental in leading UTSAs efforts to join the AISIC along with SDS core faculty and project leads Adel Alaeddini, professor of mechanical engineering and SDS associate director for academic programs, Gabriela Ciocarlie, associate professor of electrical and computer engineering, and Paul Rad, associate professor of computer science and SDS associate director of research.

The AISIC aims to advance AI safety by bringing together government, academia and industry to develop and deploy trustworthy and safe AI systems. Through collaboration and guidance, the consortium seeks to set standards, promote AI development practices and cultivate a skilled AI workforce.

The U.S. government has a significant role to play in setting the standards and developing the tools we need to mitigate the risks and harness the immense potential of artificial intelligence, said U.S. Secretary of Commerce Gina Raimondo. President Biden directed us to pull every lever to accomplish two key goals: set safety standards and protect our innovation ecosystem. Thats precisely what the U.S. AI Safety Institute Consortium is set up to help us do.

The SDS is the only school of its kind at a Tier One, Hispanic Serving Institution. The school was established to educate top data scientists for Texas workforce while leading the nation in data-intensive research. Its commitment to excellence, innovation and community engagement makes it a hub for data-driven and AI-powered solutions and a driving force in the ever-evolving data and AI landscape.

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Computer scientist wins NSF CAREER Award to advance Alzheimer’s research using AI | Wake Forest News – Wake Forest News

In her groundbreaking work as a computer scientist, assistant professor Minghan Chen is using artificial intelligence to create new techniques to better understand the mechanisms behind Alzheimers disease and predict its progression across brain networks.

Chen was recently awarded a five-year, $500,000 National Science Foundation CAREER Award for her research project entitled: Towards a Living Neuron Twin for Improving Human Cognitive Health.

My NSF research project will work by developing a holistic computational framework called Neuron Twin, said Chen. This pioneering framework will combine two powerful algorithmic approaches multiscale modeling and deep learning.

Her research will help facilitate the analysis and comprehension of complex medical and health data and will help medical researchers address emerging questions in health data science.

Chens work proposes techniques that will help overcome limitations of other contemporary work in this area, including techniques for the integration of diverse types of data, handling of small data sets, and building of interpretable models, said William Turkett, associate professor and chair of the computer science department. The findings of her work are expected to be highly valuable facilitating the development of treatment strategies and personalized medicine for Alzheimers disease.

Alzheimers disease is a fatal and devastating cognitive disorder that affects millions of people worldwide. Currently, there is no effective treatment.

By developing a better understanding of the diseases mechanisms, we can improve early diagnosis and treatment, ultimately improving the quality of life for patients and their families, Chen said. Such a framework can be transferred for use in broader applications of neurodegenerative diseases, including but not limited to Parkinsons disease and Lewy body dementia that share similar disease pathogenesis and therapeutic challenges.

For Chen, the NSF CAREER Award is more than an opportunity to grow in her field. She was inspired to pursue this project by her passion for applying computer science to solve real-world health challenges.

As a child, I was always interested in how things work, which naturally led me to computer science, Chen said. My interest in healthcare applications was further fueled by my parents, who are doctors. Witnessing people struggling with incurable illnesses like cancer and brain diseases made me realize the profound impact technology can have on advancing healthcare and alleviating societal burdens.

In addition to the research, there is also an outreach component to the CAREER award. Wake Forest undergraduate and graduate students will work with Chen on the project. Workshops, seminars, and other educational activities both on campus and in the local community are also being planned.

Chen is developing a new interdisciplinary course on modeling and learning for Wake Forest students as well as a summer boot-camp on those topics open to students at other universities.

She has curated strategic partnerships for her work. Collaborating institutions include the Alzheimers Disease Research Center, which will help disseminate and apply her findings in the clinical setting, and the UNC-Chapel Hill Advanced Medicine Laboratory.

Winning an NSF CAREER Award is more than just an achievement for me; its a significant encouragement and support, said Chen. As a female researcher, it recognizes the impact and potential of my work, which is particularly meaningful in a field where women are underrepresented. This recent award provides me with the resources and support to further advance my research, enabling me to make a more substantial contribution across the fields of computer science and medical and health science.

Chen is one of six WFU winners of NSF CAREER Awards announced within the past year. This includes faculty members from the physics, chemistry, math and statistics and engineering departments.

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SDSC and University of Utah Pioneer $6M National Data Platform for Equitable Scientific Research – HPCwire

March 6, 2024 The San Diego Supercomputer Center (SDSC) at UC San Diego and the University of Utah (Utah) have announced a national-scale pilot project, called the National Data Platform (NDP), aimed at a service ecosystem to make access to and use of scientific data open and equitable across a broad range of communities, including traditionally underrepresented researchers.

Led by SDSC and Utahs Scientific Computing and Imaging Institute (SCI), and in partnership with the EarthScope Consortium, the $6 million NDP pilot is funded by the U.S. National Science Foundation. The pilot will serve as a federated and extensible data and service ecosystem to foster innovation, discoveries and collaboration through the equitable access and use of science data and leveraging existing national cyberinfrastructure capabilities.

Such access and use will ensure responsible data-driven research to address urgent national and global issues such as climate change and environmental sustainability.

Additionally, with the increasing potential of artificial intelligence (AI) to enhance and accelerate solutions to many scientific and societal problems, broad and equitable access to AI-ready data repositories is essential in developing and deploying responsible AI models and enabling everyone to be a part of AI-integrated solutions.

NDP aims to bridge the gaps between data innovations and computing infrastructure through the combination of a data hub and an extensible service platform. Carefully designed workflows based on user needs assessment aim to bring equity for everyone to participate in AI-integrated solutions for research discoveries and global societal challenges, SDSCs Chief Data Science Officer and NDP Principal Investigator Ilkay Altintas said.

SDSC Director Frank Wrthwein explained that NDP builds a data and knowledge curation layer on top of low level content delivery networks like the Open Science Data Federation, thus leveraging prior and contemporary investments in cyberinfrastructure across dozens of academic institutions.

Utahs SCI Director Manish Parashar said, With the growing importance of data to all aspects of science and society, there is an urgent and critical need for open and equitable access to scientific data. Open and equitable access to scientific data can democratize science and transform society. NDP aims to create a robust, scalable and agile data platform that can enable such access.

According to SCI Research Computer Scientist and NDP Co-Principle Investigator Ivan Rodero, NDP redefines cyberinfrastructure by setting new standards for data access and collaborative science. NDP will enable a seamless integration of data services, ensuring that every researcher has the required tools to push the boundaries of discovery, he said.

About NDP

NDP is a federated and extensible data and service ecosystem aimed at promoting collaboration, innovation and open and equitable use of data on top of existing national cyberinfrastructure and cloud capabilities. The platform aims to remove barriers involving access and use of data and computing.

About SDSC

The San Diego Supercomputer Center at the University of California San Diego is a leader in high-performance and data-intensive computing and cyberinfrastructure. SDSC provides resources, services and expertise to the local, regional and national research community, including industry and academia. It supports hundreds of multidisciplinary programs spanning a wide variety of domains.

About SCI

The Scientific Computing and Imaging (SCI) Institute is a multidisciplinary research institute at the University of Utah. SCI is internationally recognized as a leader in visualization, scientific computing and image analysis, focusing on the transformation of science and society through translational research and innovation in computer, computational and data science.

Source: SDSC

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Eastern Oregon University’s Computer Science Program Ranked Among Top 10 in the Nation – The Voice

La GRANDE, Oregon Eastern Oregon University (EOU) has been recognized as one of the top 10 online computer science programs in the United States by HostingAdvice.com, a leading authority in web hosting and technology education. This acknowledgment highlights EOUs commitment to providing high-quality education in the rapidly growing field of computer science.

The website pointed out that the designation comes as no surprise given the increasing demand for skilled professionals in the computer science industry. According to HostingAdvice.com recent statistics show, the field is projected to grow by 15% between 2021 and 2031, with approximately 683,000 new jobs anticipated a rate three times faster than the national average for all occupations.

EOUs computer science program stands out not only for its academic excellence but also for its affordability and commitment to individualized attention.

With a focus on affordability, EOU offers one of the lowest costs per credit hour among the programs listed by HostingAdvice.com.

Prospective students interested in learning more about EOUs computer science program and other offerings can visit the universitys website at http://www.eou.edu.

EOU offers a wide range of undergraduate and graduate programs in fields such as education, business, science, and the arts. With a commitment to accessibility, affordability, and student success, EOU provides a supportive learning environment where students can thrive both academically and personally.

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Scientists shine new light on the future of nanoelectronic devices – Argonne National Laboratory

Artificial intelligence (AI) has the potential to transform technologies as diverse as solar panels, in-body medical sensors and self-driving vehicles. But these applications are already pushing todays computers to their limits when it comes to speed, memory size and energy use.

Fortunately, scientists in the fields of AI, computing and nanoscience are working to overcome these challenges. And they are using their brains as their models.

That is because the circuits, or neurons, in the human brain have a key advantage over todays computer circuits: they can store information and process it in the same place. This makes them exceptionally fast and energy efficient. That is why scientists are now exploring how to use materials measured in billionths of a meter nanomaterials to construct circuits that work like our neurons. To do so successfully, however, scientists must understand precisely what is happening within these nanomaterial circuits at the atomic level.

The XPCS measurement would not be possible without the coherent X-ray beam from the APS. Qingteng Zhang, assistant physicist, APS at Argonne.

Recently, a team of researchers including scientists from the U.S. Department of Energys (DOE) Argonne National Laboratory pioneered a novel way of evaluating exactly that. Specifically, they used the Advanced Photon Source (APS), a DOE Office of Science user facility, to examine the changes that occur in the structure of a specific nanomaterial as it changes from conducting an electrical current to not. This mimics the switching between on and off states in a neural circuit.

In these materials, the conducting state, or phase, is controlled by imperfections in the material (or point defects) at the atomic level. By putting a strain on the nanomaterial, researchers can alter the concentration and change the position of these defects. This changes the pathway of electron flow. However, these defects are constantly moving, which changes the materials conducting and non-conducting regions. Until now, this motion has been extremely difficult to study.

There has been a lot of research about the occurrence and nature of defects in nanomaterials, explained Dillon Fong, a materials scientist at Argonne. But we knew very little about the dynamics of these defects when a material changes phase. We wanted to show that you can use X-rays to examine transitions between conducting and non-conducting phases in nanomaterials under conditions similar to those under which these materials will be used. The team demonstrated how the APS can help make this possible.

For the experiment, the researchers chose a material, SrCoOx,that easily switches between the conducting and non-conducting, insulating, phases. To see the fluctuation between the conducting phase and the insulating phase at the nanoscale, they used a technique called X-ray photon correlation spectroscopy (XPCS). This is enabled by the highly coherent X-ray beams from the APS. XPCS can directly measure how fast the material fluctuates between different phases at the atomic scale, even when these fluctuations are barely detectable.

The XPCS measurement would not be possible without the coherent X-ray beam from the APS, said Qingteng Zhang, an assistant physicist at the APS who led the X-ray measurements. In addition, it is important that we take the measurement under the same conditions that the material will operate under. This allows us to learn how the material will behave while performing its intended function. However, such environmental control usually requires sealing the sample in a chamber or a dome. This is where the highly penetrating X-ray beam from the APS is extremely helpful. Because while the chamber window or the dome shell is opaque to visible light, we can make either one completely transparent to the X-rays.

The APS upgrade now underway will increase the brightness of the APS X-rays by up to 500 times upon its completion in 2024. This will significantly increase the speed of measurement as well as the quality of coherent X-ray techniques, including XPCS. This could create unprecedented scientific opportunities for researchers around the world.

That is an exciting prospect for Panchapakesan Ganesh, a researcher at DOEs Oak Ridge National Laboratory (ORNL). He led the theoretical work in the study along with his team members Vitalii Starchenko, ORNL, and Guoxiang Hu, now an assistant professor at Georgia Tech.

High-quality data from experiments like these are critical to our ability to develop theories and build models that can capture what happens in nanoelectronic materials when they go from conducting to non-conducting phases, Ganesh said. For example, we need to learn how energy dissipates in these systems if we are going to develop nanodevices that approach the energy efficiency of our brains. No single computational approach can solve this type of problem on its own. We need the best inputs from both the experimental and computational science sides to advance this nanoscale understanding. Our integrated approach is a perfect example of that, and we think it will spur more research in this exciting new field.

The work was funded by the DOE Office of Basic Energy Sciences. Fong and his fellow researchers describe the experimental details and their findings in Advanced Materials. Besides Fong and Zhang, other Argonne authors include E. M. Dufresne, H. Zhou, Y. Dong, A. R. Sandy, G. E. Sterbinsky, G. Wan, I. C. Almazan and H. Liu.

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Webster University Computer Science Club Programs its Future by Participating in ICPC Mid-Central Regional Contest – Webster University Newsroom

The Webster University Computer Science Club Coding Team: from left: Zach McColgan, Urmat Urustemov, Muaz Mohammed, Divyam Arora, and Zach Novak.

Webster Universitys Computer Science Club (CS Club) recently competed in the International Collegiate Programming Contest (ICPC) Mid-Central Regional Contest for the first time in four years. The event was held in Cape Girardeau at Southeast Missouri State University. Two coding teams from the CS Club participated the Golden Gorloks, which consisted of upperclassmen Divyam Arora, Zach McColgan and Urmat Urustemov, and the Gorlok Blues, comprised of underclassmen Muaz Mohammed and Zach Novak.

The International Collegiate Programming Contest is an algorithmic programming contest for college students. Teams of three, representing their university, work to solve real-world problems, fostering collaboration, creativity, innovation, and the ability to perform under pressure. Through training and competition, teams challenge each other to raise the bar on the possible. ICPC is the oldest and largest programming contest in the world.

Although the ICPC Competition is typically held in November, the 2023 competition was held in February 2024 due to a postponement resulting from the COVID-19 pandemic.

Participating in the ICPC Mid-Central Regional Contest was an incredible experience for our Coding Team, said Arora, who serves as the Coding Team lead. It was our very first ICPC competition, and we gained invaluable experience that will undoubtedly shape our future endeavors. The challenges were both exciting and thought-provoking, and the team worked seamlessly to navigate them."

The Golden Gorloks team smiles for a quick photo during the competition.

During the competition, the Golden Gorloks solved five questions, which was the maximum number of questions solved by any team at the site. They placed 42nd out of 87 teams. The Gorlok Blues placed 79th out of 87 teams.

I enjoyed the whole experience - I was not expecting it to be as inviting as it was, but that really helped my nerves, shared Zach Novak, a sophomore from the Gorlok Blues team. I learned a lot about teamwork when it comes to coding and how it's not always a one-man job, as well as how to use my voice to share my thoughts which help further the discussion. This first competition and hopefully many more will benefit my future as a programmer. Getting to experience a more stressful coding environment helps build confidence. Additionally, the networking and communication aspects of the conference helped strengthen my skills and build my professional network.

Zach Novak and Muaz Mohammed, both members of the Gorlok Blues team.

These coding teams are made up of bright and intelligent students, said Lasanthi Gamage, coach of the CS Club and associate professor in Websters department of Computer & Information Sciences. More importantly, they are self-motivated and dedicated students who are full of determination. I am happy to see how they came from different levels of knowledge and worked together. They continually support each other to grow. During the competition, they practiced interpersonal communications while problem-solving, learning from their mistakes to perform even better.

Arora is already looking forward to future competitions for the Webster University CS Club.

I can confidently say that our team is not only planning to participate again next year but is determined to secure an even higher position. The lessons learned from this competition have fueled our enthusiasm, and we are committed to honing our skills and strategies for a more competitive edge. We're excited about the opportunity to build on this foundation and showcase the growth of our Coding Team in the coming year.

The 2024 ICPC competition will be held as per usual in November 2024.

The Computer Science Club at Webster University aims to provide students with hands-on tech experience, professional networking opportunities and peer support for all members. After being reinstated with a new constitution and vision in 2020, it has become one of the fastest growing clubs on campus, welcoming nearly 50 new members for the current academic year alone.

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How I Learned to Concentrate – The New Yorker

I arrived at M.I.T. in the fall of 2004. I had just turned twenty-two, and was there to pursue a doctorate as part of something called the Theory of Computation groupa band of computer scientists who spent more time writing equations than code. We were housed in the brand-new Stata Center, a Frank Gehry-designed fever dream of haphazard angles and buff-shined metal, built at a cost of three hundred million dollars. On the sixth floor, I shared an office with two other students, one of many arranged around a common space partitioned by a maze of free-standing, two-sided whiteboards. These boards were the groups most prized resource, serving for us as a telescope might for an astronomer. Professors and students would gather around them, passing markers back and forth, punctuating periods of frantic writing with unsettling quiet staring. It was common practice to scrawl DO NOT ERASE next to important fragments of a proof, but I never saw the cleaning staff touch any of the boards; perhaps they could sense our anxiety.

Even more striking than the space were the people. During orientation I met a fellow incoming doctoral student who was seventeen. He had graduated summa cum laude at fifteen and then spent the intervening period as a software engineer for Microsoft before getting bored and deciding that a Ph.D. might be fun. He was the second most precocious person I met in those first days. Across from my office, on the other side of the whiteboard maze, sat a twenty-three-year-old professor named Erik Demaine, who had recently won a MacArthur genius grant for resolving a long-standing conjecture in computational geometry. At various points during my time in the group, the same row of offices that included Erik was also home to three different winners of the Turing Award, commonly understood to be the computer-science equivalent of the Nobel Prize. All of this is to say that, soon after my arrival, my distinct impression of M.I.T. was that it was preposterousmore like something a screenwriter would conjure than a place that actually existed.

I ended up spending seven years at M.I.T.five earning my Ph.D. and two as a postdoctoral associatebefore taking a professorship at Georgetown University, where Ive remained happily ensconced ever since. At the same time that my academic career unfolded, I also became a writer of general-audience books about work, technology, and distraction. (My latest book, Slow Productivity, was published this month.) For a long time, I saw these two endeavors as only loosely related. Only recently have I realized that my time at M.I.T. may be the source of nearly every major idea Ive chased in my writing. At the Theory of Computation group, I got a glimpse of thinking in its purest form, and it changed my life.

A defining feature of the theory group was the explicit value that the researchers there placed on concentration, which I soon understood to be the single most important skill required for success in our field. In his book Surely Youre Joking, Mr. Feynman!, the Nobel Prize-winning physicist Richard P. Feynman recalled delivering his first graduate seminar at Princeton, to an audience that included Albert Einstein and Wolfgang Pauli: Then the time came to give the talk, and here are these monster minds in front of me, waiting! At M.I.T., we had our own monster minds, who were known for their formidable ability to focus.

I was astonished at how the most impressive of my colleagues could listen to a description of a complicated proof, stare into space for a few minutes, and then quip, O.K., got it, before telling you how to improve it. It was important that they didnt master your ideas too quickly: the dreaded insult was for someone to respond promptly and deem your argument trivial. I once attended a lecture by a visiting cryptographer. After he finished, a monster mind in the audiencean outspoken future Turing winnerraised his hand and asked, Yes, but isnt this all, if we think about it, really just trivial? In my memory, the visitor fought back tears. In the theory group, you had to focus to survive.

Another lesson of my M.I.T. years was the fundamental separation between busyness and productivity. Scientists who work in labs, and have to run experiments or crunch numbers, can famously work long hours. Theoreticians cant, as theres only so much time you can usefully think about math. Right before a paper deadline, you might push hard to get results written up. On the other hand, weeks could go by with little more than the occasional brainstorming session. An average day might require two or three hours of hard cogitation.

The idea of taking your time to find the right idea was central to my experience. As a graduate student, I was sent all around Europe to present papers at various conferences. The meetings themselves werent the point. It was the conversations that matteredone good idea, sparked on a rooftop in Bologna or beside Lake Geneva in Lausanne, was worth days of tiring travel. But despite long periods of apparent lethargy, we still were productive. By the time I left M.I.T. to start my job at Georgetown, I had already published twenty-six peer-reviewed papersand yet Id never really felt busy.

Finally, there were those whiteboards. The theory group was a collection of proudly marker-on-board thinkers, surrounded by more hands-on computer scientists who were actually programming and building tangible new things. They honed concrete inventions; by contrast, our patron saint was Alan Turing, whod completed his foundational work on the theory of computation before electronic computers were even invented. In a setting otherwise obsessed with artificial marvels, we developed a pro-human chauvinism. We were computer scientists, but we were skeptical that digital tools could be more valuable than human cognition and creativity.

The culture at M.I.T. was intense to the point of being exclusionary. If your output wasnt laser-focussed, the system would quietly shunt you away. (The doctoral program included an ambiguous requirement called the research qualifying exam, which provided a natural checkpoint at which students who werent producing publications could move on to other opportunities.) This approach makes perfect sense for an institution trying to train the worlds technical lite, but it cant be easily exported to a standard workplace. Most organizations are not made up of a bunch of Erik Demaines.

Still, starting from these specialized roots and then moving on to write for more general audiences, Ive come to believe that these narrow extremes still somehow embody broad truths. Too many of us undervalue concentration, and substitute busyness for real productivity, and are quick to embrace whatever new techno-bauble shines brightest. You dont have to spend hours staring at whiteboards or facing down monster minds for these realizations to ring true. M.I.T. is preposterousbut in its particulars it may have also isolated something that the rest of us, deep down, know is important.

Slow Productivity, my newest book, is ostensibly about work. It rejects a notion of productivity based on activity, and instead promotes a slower alternative based on real value produced at a more humane pace. When I wrote it, I didnt realize that I was inspired by the eccentric theoretical computer scientists with whom I once loafed around the Stata Center. But I was. Decades later, I still think they were doing something right.

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SheTech: Inspiring the next generation of women in tech – Utah Business – Utah Business

What happens when you fail your first computer science test in high school?

You get an internship at Microsoft in college.

In colleges and universities around the world, women are less likely to complete their STEM degrees than men (48 percent vs. 65 percent). But the sadder numbers are all the women who never even make it that far. Research shows that many women dont embark on STEM paths because they dont believe theyre capable, even though the same study shows they are just as prepared as men. Women are more likely to feel marginalized as an isolated minority in their fields before they even hit the workforce, where numbers for recruitment and retention worsen. The courses are hard, job prospects are competitive, and finding a woman in any of these roles is challenging. With this outlook, they often drop out.

If both genders are entering college equally prepared, but women dont believe there is a space for them, it wont matter how well they learned coding or how great their teachers were. We will never increase the number of women in the tech talent pipeline until we change their perception of whats possible. Without them, well be missing essential insights and ideas to solve our biggest problems.

Angela was smart, ambitious and bravely taking on the challenge of being one of the few girls in her high school advanced computer science class. Angela was interested in the field, but an experience challenged her confidence. After an insane amount of work, she failed her first computer science test. Her hard work should have indicated otherwise, but this feedback led her to conclude that computer science wasnt for her, as if her brain wasnt made to do this kind of work and she shouldnt continue.

Just in time, a friend told her about a program called SheTech, where she could meet women working in technology jobs and find out what its like to work in STEM. Angela attended SheTech Explorer Day, hoping to be introduced to an alternative field to computer science where she would feel more confident. Instead, she learned about more computer science jobs than she ever imagined. Angela met dozens of women working in the field whose work and personal journeys were fascinating, and they took the time to talk to Angela about her interests and future.

At SheTech Explorer Day, Angela was assured that she was capable of success and the courses she was taking were challenging for everyone. Stories about their own struggles and setbacks helped her see that there was a place for her in STEM. This experience inspired Angela to change her mind about herself and keep going with a new vision of what was possible in her personal future.

Today, Angela is at the University of Utah studying (you guessed it!) computer science. Angela finished high school as the Utah Sterling Scholar in computer technology and now excels in her college studies. She recently completed an internship at Microsoft. College courses are far more challenging than the ones she started with in high school, but she tries again when she gets stuck, and no setback or failure will remove her confidence in her chosen career path. The trajectory of Angelas entire life changed because real women in STEM inspired her to keep going and do more than she ever thought possible.

This is the kind of activation we need for all girls. No matter what theyre interested in, they deserve the chance to see how technology is a part of that field and that theres a path for them in STEM with so many opportunities and possibilities.

The next SheTech Explorer Day is on March 14, 2024. No matter where you work or live, talk to the high school girls you know about their interests, their future and the opportunities waiting for them in tech. Help them sign up so they can connect with role models who will inspire them and bolster the trajectory of their lives. We need them in STEM, and they need us to help them see how true that is.

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SheTech: Inspiring the next generation of women in tech - Utah Business - Utah Business

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