At the core of GKC is a series of classes and initiatives that combine STEM skills with policy know-how in a way that’s meant to encourage students to leverage entrepreneurship and innovation in order to develop rapid, scalable solutions to national security issues. Students from both undergraduate and graduate level programs, regardless of their prior experience in national defense, are encouraged to participate.

“We’re really trying to empower students to pursue national security-relevant work while they’re here at Stanford,” explains Joe Felter, GKC’s director, co-founder, and senior research scholar at CISAC. FSI and CISAC have deep roots in this type of innovative, interdisciplinary approach to policy solutions GKC is working to implement. Michael McFaul, FSI’s director, is a founding faculty member and principal investigator for GKC, and David Hoyt, the assistant director of GKC, is an alumnus of the CISAC honors program.

Results from GKC’s classes have been very encouraging so far. Working through "Hacking for Defense," a GKC-affiliated class taught out of the MS&E department, Jeff Jang, a new Defense Innovation Scholar and MBA student, showed how implementing a rapid interview process and focusing on problem and customer discovery has allowed his team to create enterprise software for United States Air Force (USAF) fleet management that has vastly improved efficiency, reduced errors and enabled better planning capabilities into the workflow. Their product has been given numerous grants and awards, and the team has received signed letters of interest from 29 different USAF bases across the world.

In another GKC class, "Technology, Innovation, and Great Power Competition,” Abeer Dahiya and Youngjun Kwak, along with Mikk Raud, Dave Sprague and Miku Yamada — three students from FSI’s Ford Dorsey Master’s in International Policy program (MIP) — have been tackling the challenges involved in developing a domestic U.S. semiconductor strategy. They were among the student teams asked to present the results of their work to Dep. Sec. Hicks during her visit.

“Attending this class has been one of the highlights of my time at Stanford,” says Mikk Raud (MIP ‘22). “It’s been a great example of how important it is to run interdisciplinary courses and bring people from different fields together.”

He continues, “As a policy student, it was very insightful for me to learn from my peers from different programs, as well as make numerous visits to the engineering quad to speak to technical professors whom I otherwise would have never met. After meeting with and presenting to Deputy Secretary Hicks and hearing about the work other students are doing, it really hit home to me that the government does listen to students, and it really is possible that a small Stanford group project can eventually lead into significant changes and improvements of the highest levels of policy making.”

This kind of renewed interest in national security and defense tech among students is precisely what the Gordian Knot Center is hoping to foster. Building an interconnected innovation workforce that can “think deeply, [and] act quickly,” GKC’s motto, is a driving priority for the center and its supporters.

The Department of Defense recognizes the value of this approach. In her remarks, Dep. Sec. Kathleen Hicks acknowledged that reshaping the culture and methodologies by which the DoD runs is as imperative as it is difficult.

“My life is a Gordian knot, day in and day out at the Defense Department,” she quipped. Speaking seriously, she reminded the audience of the tremendous driving power DoD has had in creating future-looking national security defenses.  “Because of its sophistication, diversity, and capacity to innovate, the U.S. Defense Industrial Base and vibrant innovation ecosystem remains the envy of the world,” Hicks emphasized. “Every day, people like you are designing, building, and producing the critical materials and technologies that ensure our armed forces have what they need.”

But she also recognized that the challenges facing the DoD are real and complex. “There are many barriers in front of the Department of Defense in terms of what it takes to operate in government and to make the kinds of shifts we need in order to have the agility to take advantage of opportunities and partner effectively.” She reiterated that one of her key priorities is to accelerate innovation adoption across DoD, including organizational structure, processes, culture, and people.

Partnerships with groups like the Gordian Knot Center are a key component to breaking down the barriers to innovation facing our national institutions and rebuilding them into new, more adaptable bridges forward. While the challenges facing the Department of Defense remain significant, the work of the students in GKC’s classes so far proves that progress is not only possible, but can be made quickly as well.

It’s a quintessential Silicon Valley scene. A group of tech-savvy Stanford students are delivering a passionate pitch about a product they hope is going to change the world, while a room full of venture capitalists, angel investors and entrepreneurs peppers them with questions.

But there’s a twist. This Stanford classroom is also packed with decorated military veterans and active duty officers. And a group of analysts from the U.S. intelligence community is monitoring the proceedings live via an iPad propped up on a nearby desk.

These Stanford students aren’t just working on the latest “Uber for X” app. They’re searching for solutions to some of the toughest technological problems facing America’s military and intelligence agencies, as part of a new class called Hacking for Defense.

A student team briefs the class on a wearable sensor they're developing for an elite unit of U.S. Navy SEALs – a product they're pitching as "fitbit for America's divers."

Kulkarni’s team is working with an organization within the US Department of Defense to devise a system that will provide virtual assistance to Afghan and Iraqi coalition forces as they defuse deadly improvised explosive devices.

“At Stanford there’s a lot of opportunities for you to build things and go out and learn new stuff, but this was one of the first few opportunities I’ve seen where as a Stanford student and as an engineer, I can go and work on problems that will actually make a difference and save lives,” said Kulkarni.

A 21st century tech ROTC

That’s exactly the kind of “21st century tech ROTC” model of national service that Steve Blank, a consulting associate professor at Stanford’s Department of Management Science and Engineering, said he had in mind when he developed the class.

“The nation is facing a set of national security threats it’s never faced before, and Silicon Valley has not only the technology resources to help, but knows how to move at the speed that these threats are moving at,” said Blank.

MBA student Rachel Moore presents for Team Sentinel, which is working with the U.S. 7th Fleet to find better ways to analyze drone and satellite imagery.

Former U.S. Army Special Forces Colonel Joe Felter, who helped create the class and co-teaches it with Blank, said the American military needs to find new ways to maintain its technological advantage on the battlefield.

“Groups like ISIS, al–Qaeda and other adversaries have access to cutting edge technologies and are aggressively using them to do us harm around the world,” said Felter, who served in Iraq and Afghanistan and is currently a senior research scholar at Stanford’s Center for International Security and Cooperation (CISAC) and research fellow at the Hoover Institution.

“The stakes are high – this is literally life and death for our young men and women deployed in harm’s way. We’re in a great position here at Stanford and in Silicon Valley to help make the connections and develop the common language needed to bring innovation into the process, in support of the Department of Defense and other government agencies’ missions.”

Startup guru Steve Blank shares a light moment with a group of students.

“It’s like a smorgasbord of all these people coming together from different parts and different schools of Stanford, and so I think that’s just a really cool environment to be in,” said Rachel Moore, a first-year MBA student.

Moore’s team includes electrical and mechanical engineering students, and they’re working together to develop a system to enable the Navy’s Pacific Fleet to automatically identify enemy ships using images from drones and satellites.

Tough technological challenges

Months before the course start date, class organizers asked U.S. military and intelligence organizations to identify some of their toughest technological challenges.

Class co-teacher Pete Newell throws his hands up to celebrate a student breakthrough.

The Navy Special Warfare Group asked students to design wearable sensors for Navy SEALs, so they could monitor their physiological conditions in real-time during underwater missions.

Intelligence and law enforcement agencies were interested in software that could help identify accounts tied to malicious “catfishing” attempts from hackers trying to steal confidential information.

And those were just a few of the 24 problems submitted by 14 government agencies.

Developing Solutions

The class gives eight teams of four students 10 weeks to actively learn about the problem they are addressing from stake holders and end users most familiar with the problem and to iteratively develop possible solutions or  a “minimum viable product,” using a modified version of Steve Blank’s “lean launchpad methodology,” which has become a revered how-to guide among the Silicon Valley startup community.

Rachel Olney, a graduate student in mechanical engineering, tries on a military-grade dry suit on a visit to the 129th Rescue Wing at Moffett Field.

“If you’re not crawling in the dirt with these guys, then you don’t understand their problem,” Blank told the class.

One student team, which was working on real-time biofeedback sensors and geo-location devices for an elite team of Navy SEALS (a project they were initially pitching at “fitbit for America’s divers”), earned a round of applause from the class when they showed a slide featuring photos from a field trip they took to the 129th Rescue Wing at Moffett Field to find out what it felt like to wear a military-grade dry suit.

Rachel Olney, a graduate student in mechanical engineering, said the experience of squeezing into the tight suit and wearing the heavy dive gear gave her a better appreciation for the physical demands that Navy SEALs have to deal with during a mission.

“They’re diving down to like 200 feet for up to six to eight hours…and during that time they can’t eat, they can’t hydrate, they’re physically exerting a lot, because they’re swimming miles and miles and miles at depth and they can’t see and they can’t talk to each other,” Olney said.

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Another group came in for some heavy criticism from the teaching team for failing to identify and interview enough end users.

But the next week, they were back in front of the class showing a video from a team member’s visit to an Air Force base in Fresno, where he logged some time inside the 90-pound bomb suit that explosive ordinance disposal units wear in the field.

“You can’t address a customer issue unless and until you really step into the shoes of the customer,” said Gaurav Sharma, who’s a student at Stanford's Graduate School of Business.

“That was the exact reason why I went to Fresno and wore the bomb suit, to get into the shoes of the end customer.”

Navigating the defense bureaucracy

Active duty military officers from CISAC’s Senior Military Fellows program and the Hoover Institution’s National Security Affairs Fellows program act as military liaisons for the class and help students navigate the complex defense bureaucracy.

“[The students] have really just jumped in with both feet and immersed themselves in this Department of Defense world that for so many civilians is just very foreign to them,” said U.S. Army Colonel John Cogbill, who has spent the last year as a senior military fellow at CISAC.

“I think they will come away from this experience with a much better appreciation of what we do inside the Department of Defense and Intelligence community, and where there are opportunities for helping us do our jobs better.”

Cogbill said he hoped that some of the inventions from the class, like an autonomous drone designed to improve situational awareness for Special Forces teams, could help the troops on his next combat deployment, where he will serve as the Deputy Commanding Officer of the U.S. Army’s elite 75th  Ranger Regiment.

“It’s not just about making them more lethal, it’s also about how to keep them alive on the battlefield,” said Cogbill.

Students also get support from their project sponsors and personnel at the newly established Defense Innovation Unit Experimental (DIUx) stationed at Moffett Field.

Tech saves lives on the battlefield

Another key member of the teaching team is Pete Newell, who was awarded the Silver Star Medal (America’s third-highest military combat decoration), for leading a U.S. Army battalion into the Battle of Fallujah, where he survived an ambush and left the protection of his armored vehicle in an attempt to save a mortally wounded officer.

Class co-teacher and Silver Star Medal recipient Pete Newell explains some of the classic reasons why military products fail in the field.

“What I realized is that the guys on the front edge of the battlefield who were actually fighting the fight, don’t have time to figure out what the problem is that they have to solve,” Newell said.

“They’re so involved in just surviving day to day, that they really don’t have time to step back from it and see those problems coming, and what they needed was somebody to look over their shoulder and look a little deeper and anticipate their needs.”

One of the first and most urgent problems Newell faced on the job was responding to the sudden spike in IED attacks on dismounted infantry.

The Army was still using metal detector technology from the ‘50s to find mines, but the new breed of IEDs, which were often hidden inside buried milk jugs, were virtually undetectable to the outdated technology.

Former U.S. Army Colonel Pete Newell demystifies some military jargon for the class.

Newell’s solution was a handheld gradiometer, the kind of technology used to find small wires in your backyard during a construction project, paired with a ground penetrating radar that can see objects underground.

But by the time the new technology reached troops in the field last summer, more than 4,000 had been wounded or killed in IED attacks.

Newell said he hoped the class would help get life-saving technology deployed throughout the military faster.

“I think it’s important to enable this younger generation of technologists to actually connect with some of the national security issues we face and give them an opportunity to take part in making the world a safer place,” Newell said.

Tom Byers, an entrepreneurship professor in Management Science and Engineering and faculty director of the Stanford Technology Ventures Program, rounds out the teaching team and brings his experience in innovation education and entrepreneurship to the classroom.

Inspiring the next generation

Students said the opportunity to find solutions to consequential problems was their primary inspiration for joining the class.

“When I first came to Stanford, the hype around entrepreneurship was very much around, ‘go out, make an app, do something really fun and cool, and get rich’,” said Darren Hau, a junior in Electrical Engineering.

Students share a laugh during a class break.

Felter said he was humbled that so many students were willing to serve in this way.

“It’s encouraging to find out that students at one of our top universities are very interested and highly motivated to work very hard and use their skills and expertise and talent and focus it on these pressing national security problems,” said Felter.

The teaching team said they planned on expanding their class to other universities across the country in the coming years, to create a kind of open source network for solving unclassified national security problems.

For military officers like Cogbill, who will likely soon be leading U.S. soldiers into combat, that’s welcome news.

“Every time you run a course, that’s eight more problems,” Cogbill said.

“If this scales across 10, 20, 30, 40 more universities, you can imagine how many more problems can be solved, and how many more lives can potentially be saved.”