There’s good earnings news for U.S. members: Salaries are rising. Base salaries increased by about 5 percent from 2022 to 2023, according to the IEEE-USA 2024 Salary and Benefits Survey Report.

Last year’s report showed that inflation had outpaced earnings growth but that’s not the case this year.

In current dollars, the median income of U.S. engineers and other tech professionals who are IEEE members was US $174,161 last year, up about 5 percent from $169,000 in 2022, excluding overtime pay, profit sharing, and other supplemental earnings. Unemployment fell to 1.2 percent in this year’s survey, down from 1.4 percent in the previous year.

As with prior surveys, earned income is measured for the year preceding the survey’s date of record—so the 2024 survey reports income earned in 2023.

To calculate the median salary, IEEE-USA considered only respondents who were tech professionals working full time in their primary area of competence—a sample of 4,192 people.

Circuits and device engineers earn the most

Those specializing in circuits and devices earned the highest median income, $196,614, followed by those working in communications ($190,000) and computers/software technology ($181,000).

Specific lucrative subspecialties include broadcast technology ($226,000), image/video ($219,015), and hardware design or hardware support ($215,000).

Engineers in the energy and power engineering field earned the lowest salary: $155,000.

Higher education affects how well one is paid. On average, those with a Ph.D. earned the highest median income: $193,636. Members with a master’s degree in electrical engineering or computer engineering reported a salary of $182,500. Those with a bachelor’s degree in electrical engineering or computer engineering earned a median income of $159,000.

Earning potential also depends on geography within the United States. Respondents in IEEE Region 6 (Western U.S.) fared substantially better than those in Region 4 (Central U.S.), earning nearly $48,500 more on average. However, the report notes, the cost of living in the western part of the country is significantly higher than elsewhere.

The top earners live in California, Maryland, and Oregon, while those earning the least live in Arkansas, Nebraska, and South Carolina.

Academics are among the lowest earners

Full professors earned an average salary of $190,000, associate professors earned $118,000, and assistant professors earned $104,500.

Almost 38 percent of the academics surveyed are full professors, 16.6 percent are associate professors, and 11.6 percent are assistant professors. About 10 percent of respondents hold a nonteaching research appointment. Nearly half (46.8 percent) are tenured, and 10.7 percent are on a tenure track.

Gender and ethnic gaps widen

The gap between women’s and men’s salaries increased. Even considering experience levels, women earned $30,515 less than their male counterparts.

The median primary income is highest among Asian/Pacific Islander technical professionals, at $178,500, followed by White engineers ($176,500), Hispanic engineers ($152,178), African-American engineers ($150,000), and Native American/Alaskan Native engineers ($148,000). The salary gap between Black engineers and the average salary reported is $3,500 more than in last year’s report.

Asians and Pacific Islanders are the largest minority group, at 14.4 percent. Only 5 percent of members are Hispanic, 2.6 percent are African Americans, and American Indians/Alaskan Natives account for 0.9 percent of the respondents.

More job satisfaction

According to the report, overall job satisfaction is higher than at any time in the past 10 years. Members reported that their work was technically challenging and meaningful to their company. On the whole, they weren’t satisfied with advancement opportunities or their current compensation, however.

The 60-page report is available for purchase at the member price of US $125. Nonmembers pay $225.

There’s good earnings news for U.S. members: Salaries are rising. Base salaries increased by about 5 percent from 2022 to 2023, according to the IEEE-USA 2024 Salary and Benefits Survey Report.

Last year’s report showed that inflation had outpaced earnings growth but that’s not the case this year.

In current dollars, the median income of U.S. engineers and other tech professionals who are IEEE members was US $174,161 last year, up about 5 percent from $169,000 in 2022, excluding overtime pay, profit sharing, and other supplemental earnings. Unemployment fell to 1.2 percent in this year’s survey, down from 1.4 percent in the previous year.

As with prior surveys, earned income is measured for the year preceding the survey’s date of record—so the 2024 survey reports income earned in 2023.

To calculate the median salary, IEEE-USA considered only respondents who were tech professionals working full time in their primary area of competence—a sample of 4,192 people.

Circuits and device engineers earn the most

Those specializing in circuits and devices earned the highest median income, $196,614, followed by those working in communications ($190,000) and computers/software technology ($181,000).

Specific lucrative subspecialties include broadcast technology ($226,000), image/video ($219,015), and hardware design or hardware support ($215,000).

Engineers in the energy and power engineering field earned the lowest salary: $155,000.

Higher education affects how well one is paid. On average, those with a Ph.D. earned the highest median income: $193,636. Members with a master’s degree in electrical engineering or computer engineering reported a salary of $182,500. Those with a bachelor’s degree in electrical engineering or computer engineering earned a median income of $159,000.

Earning potential also depends on geography within the United States. Respondents in IEEE Region 6 (Western U.S.) fared substantially better than those in Region 4 (Central U.S.), earning nearly $48,500 more on average. However, the report notes, the cost of living in the western part of the country is significantly higher than elsewhere.

The top earners live in California, Maryland, and Oregon, while those earning the least live in Arkansas, Nebraska, and South Carolina.

Academics are among the lowest earners

Full professors earned an average salary of $190,000, associate professors earned $118,000, and assistant professors earned $104,500.

Almost 38 percent of the academics surveyed are full professors, 16.6 percent are associate professors, and 11.6 percent are assistant professors. About 10 percent of respondents hold a nonteaching research appointment. Nearly half (46.8 percent) are tenured, and 10.7 percent are on a tenure track.

Gender and ethnic gaps widen

The gap between women’s and men’s salaries increased. Even considering experience levels, women earned $30,515 less than their male counterparts.

The median primary income is highest among Asian/Pacific Islander technical professionals, at $178,500, followed by White engineers ($176,500), Hispanic engineers ($152,178), African-American engineers ($150,000), and Native American/Alaskan Native engineers ($148,000). The salary gap between Black engineers and the average salary reported is $3,500 more than in last year’s report.

Asians and Pacific Islanders are the largest minority group, at 14.4 percent. Only 5 percent of members are Hispanic, 2.6 percent are African Americans, and American Indians/Alaskan Natives account for 0.9 percent of the respondents.

More job satisfaction

According to the report, overall job satisfaction is higher than at any time in the past 10 years. Members reported that their work was technically challenging and meaningful to their company. On the whole, they weren’t satisfied with advancement opportunities or their current compensation, however.

The 60-page report is available for purchase at the member price of US $125. Nonmembers pay $225.

Lesley-Ann Knee credits her father for introducing her to the world of patents. He’s an engineer who specializes in application-specific integrated circuits (ASICs) and holds several patents on technologies he developed while working for Hewlett-Packard and Microsoft.

“I would hear stories of his experiences through the patent prosecution processes,” Knee says, which taught her about different kinds of patents, the importance of documentation, and using detailed language. She remembers one litigation battle over a patent that went on for years, which her father’s company lost because someone forgot to delete information in a patent claim.

Lesley-Ann Knee

Employer:

Husch Blackwell

Occupation:

Patent Engineer

Education:

Bachelor’s degree in electrical engineering, Colorado State University, in Fort Collins

Knee, an electrical engineer, now works as a patent engineer in the patent prosecution department at the law office of Husch Blackwell, headquartered in Chicago. Under the supervision of patent attorneys, Knee helps with writing, filing, and managing patent applications with the U.S. Patent and Trademark Office (USPTO).

She is currently studying for the patent bar exam, which would qualify her to be a licensed patent agent, registered with the USPTO to help prepare and prosecute patent applications. Assuming she passes, she then intends to go to law school to become a patent attorney.

How to Become a Patent Engineer

Knee initially didn’t know what she wanted to study in college. Eventually she decided that an engineering degree offered diverse career opportunities, so she enrolled at Colorado State University, in her hometown of Fort Collins. She followed in her father’s footsteps, specializing in ASIC design, but also studied power systems and semiconductor physics and minored in mathematics. In 2022 she worked as an intern in the engine research division of Honda Research and Development, in Raymond, Ohio, where she developed a data analysis tool to help with testing heat distribution in vehicles.

After graduating from Colorado State in 2022, she decided to get a job related to patents. From January to May, she worked part-time as a patent technical intern at the law firm of Dorsey & Whitney, in Denver. “After learning about patents from the other side, I fell in love with the industry,” she says. Knee joined Husch Blackwell in June 2023.

She found that patent law has its quirky sides. One day her supervisor walked into one of the partner’s offices and saw the attorney “ripping apart a stuffed animal, guts everywhere,” she says. “[My] boss asked if the partner was okay. She explained that she had been pulled into a litigation case that depended entirely on the type of stitching used inside the stuffed animals.”

What Can Be Patented?

Here is Knee’s primer on U.S. patents and her advice for first-time inventors filing patents with the USPTO. This information isn’t intended to provide legal advice, she notes, and every country has its own patent system, with different rules and regulations. For specifics or guidance about legal matters, she recommends contacting a patent practitioner.

Knee’s first piece of advice? Don’t be afraid of filing a patent application. Two out of three patents get approved by the USPTO, she says.

“If you disclose your invention publicly and do not file an application within one year, you could be barred from receiving a patent on that exact invention.”

To receive a patent, an invention must have utility—that is, it has to be useful for some purpose—and novelty, meaning that it’s not an obvious variation of what already exists, she says. It could be a machine, a manufacturing process, or a composition of matter (that is, a novel combination of natural elements that are mixed mechanically or chemically).

Some things that can’t be patented, she says, are atomic weapons, devices for illegal pursuits, methods of administering business, mathematical discoveries, and scientific principles—with the exception of devices and methods that make use of those principles.

The USPTO has recognized a growing interest in artificial intelligence over the past few years, and in 2024 it released examples of AI patentability to give inventors guidance on the patentability of AI.“From my understanding, AI itself is not patentable,” Knee says. But using AI to invent something doesn’t necessarily make the invention unpatentable, she says.

An Overview of the Patent Process

The USPTO uses the “first to file” system for patent applications. “Whoever files an application first will have the best chance to patent an invention. Otherwise, you’re out of luck,” she says.

The patent filing process can vary widely in terms of cost and complexity, she says. Costs include filing fees and attorney fees. Smaller companies and individual inventors may qualify for discounts on USPTO fees. Costs may be higher for patent filings that require extensive modifications and lengthy communication with the patent office. Complexity depends on how much research USPTO examiners must do to determine the difference between existing inventions and the one in the filing.

For inventors interested in pursuing a patent for the first time, “I would highly recommend seeking out a patent practitioner—a patent attorney or patent agent—who offers free consultations to determine patentability, a possible action plan, cost, and a timeline for filing,” Knee says. Also, some universities have intellectual property legal offices that can advise professors and students on the patent process.

For someone who wants to file a patent themselves, here are some general steps:

1. File a provisional application when you have a proof of concept or prototype. This type of application doesn’t go through the USPTO but instead holds a place in line for your patent. Provisional applications expire after one year.
   
2. To follow up, file a nonprovisional application within one year of the first filing. This application is examined by the patent office and receives the filing date of the provisional application.
3. Promptly answer and respond to any USPTO rejections (called office actions), which explain the reasons your invention can’t be patented. Knee says it’s quite common to get a rejection. You can typically respond within three months at no cost or pay a fee for an extension of up to six months. If you don’t respond, the application will be considered abandoned.
4. If you receive a notice of allowance (NOA), celebrate! Your application is eligible to become a patent. Upon payment of some fees, you’ll receive an issue notification document showing the date when the patent will be officially granted, giving you the right to exclude others from using or selling your invention in the United States.
5. If you receive a notice called a final office action, you have two options. You can abandon the application, or you can file a request for continued examination, which requires you to pay for another round of prosecution and explain further why your invention deserves a patent.

The Value of Intellectual Property

Be careful disclosing information about your invention or selling it before filing a patent application, Knee says.“If you disclose your invention publicly and do not file an application within one year, you could be barred from receiving a patent on that exact invention,” she says. “Because of the ‘first to file’ system, if someone steals your idea by filing first, this can be hard and very expensive to reverse.” She also advises people to be careful about disclosing their inventions through social-media platforms or other communication methods.

In today’s intellectual property market, patents are currency. Knee has seen companies use patents as collateral for a loan, even when the patent application hasn’t been approved yet.

And other inventors use patents to launch their dream startup. “I have seen people use patents for help securing investors,” Knee says. But it’s not a one-and-done situation, she says. “The key is having one patent and filing additional applications that piggyback off of it. This process can be pricey but has a huge impact on stopping competitors from manufacturing similar products in a new field and protecting inventors in litigation battles.”

IEEE Fellow Mary Ellen Randall has been elected as the 2025 IEEE president-elect. She will begin serving as president on 1 January 2026.

Randall, who was nominated by the IEEE Board of Directors, received 16,389 votes in the election. Fellow S.K. Ramesh received 10,647 votes and Fellow John P. Verboncoeur received 9,412.

Randall’s Pledge to Members

1. Institute innovative products and services to ensure our mutually successful future.
   
2. Engage stakeholders (members, partners, and communities) to unite on a comprehensive vision.
3. Expand technology advancement and adoption throughout the world.
4. Execute with excellence, ethics, and financial responsibility.
5. Lead by example with enthusiasm and integrity.

At press time, the results were unofficial until the IEEE Board of Directors accepts the IEEE Teller’s Committee report in November.

Randall founded Ascot Technologies in 2000 in Cary, N.C. Ascot develops enterprise applications using mobile data delivery technologies. She serves as the award-winning company’s CEO.

Before launching Ascot, she worked for IBM, where she held several technical and managerial positions in hardware and software development, digital video chips, and test design automation. She routinely managed international projects.

Randall has served as IEEE treasurer, director of IEEE Region 3, chair of IEEE Women in Engineering, and vice president of IEEE Member and Geographic Activities.

In 2016 she founded the IEEE MOVE (Mobile Outreach using Volunteer Engagement) program to assist with disaster relief efforts and for science, technology, engineering, and math educational purposes.

The IEEE-Eta Kappa Nu honor society member has received several honors including the 2020 IEEE Haraden Pratt Award, which recognizes outstanding volunteer service to IEEE.

She was named a top businesswoman in North Carolina’s Research Triangle Park area, and she made the 2003 Business Leader Impact 100 list.

To find out who was chosen as IEEE-USA president-elect, IEEE Technical Activities vice president-elect, and more, read the full annual election results.

A new study that examined filings with the U.S. Patent and Trademark Office by the 50 top-patenting companies cited IEEE nearly three times more than any other technical-literature publisher including ACM, Elsevier, and Springer.

The organizations with the highest number of patents granted—including Amazon, Apple, IBM, Microsoft, Qualcomm, Samsung, and TSMC—referenced IEEE journals, standards, and conference proceedings in their patents more than 682,000 times during the past 20 years, according to the “Analysis of Patent Referencing to IEEE Papers, Conferences, and Standards 2004–2023” report. Prepared by intellectual property evaluation company 1790 Analytics, the report was released in June.

When broken down by technical discipline, IEEE is the most-referenced publisher in the following categories: artificial intelligence, blockchain technology, computer hardware, software, cybersecurity, the IoT, power systems, semiconductors, renewable energy, and telecommunications.

“Not only do IEEE publications frequently provide the science base for new inventions, inventions that build upon IEEE publications are more likely to be valuable in the future than inventions that do not build upon IEEE.”

Patenting AI and machine learning technologies has increased tenfold in the past 10 years, but IEEE has been able to keep pace, according to the study. More than 30 percent of AI-related patents reference IEEE publications.

The report notes that in emerging markets such as blockchain, cybersecurity, and virtual and augmented reality, IEEE receives the most references.

In the robotics and intelligent manufacturing category, more than 35 percent of patent references are to IEEE literature.

This chart shows that IEEE is cited nearly three times more than any other technical-literature publisher.1790 Analytics LLC

At 30 percent, the organization also leads in citations for patents on broadcasting technologies. IEEE registered more than twice the broadcasting citations of the nearest competitor.

For autonomous vehicles, IEEE is cited 10 times more than the next publisher.

Other areas where IEEE leads in citations include measuring, testing, and control as well as transmission.

The study also found that patents referencing IEEE papers are cited more often.

“This was shown to be true for each of the 20 technology categories we examined,” the report concludes. “This suggests that not only do IEEE publications frequently provide the science base for new inventions but that inventions that build upon IEEE publications are more likely to be valuable in the future than inventions that do not build upon IEEE.”

To download the full report or for more information, visit this website.

Many U.S. university students returning to campus this month will find their school no longer has a diversity, equity, and inclusion program. More than 200 universities in 30 states so far this year have eliminated, cut back, or changed their DEI efforts, according to an article in The Chronicle of Higher Education.

It is happening at mostly publicly funded universities, because state legislators and governors are enacting laws that prohibit or defund DEI programs. They’re also cutting budgets and sometimes implementing other measures that restrict diversity efforts. Some colleges have closed their DEI programs altogether to avoid political pressure.

The Institute asked Andrea J. Goldsmith, a top educator and longtime proponent of diversity efforts within the engineering field and society, to weigh in.

Goldsmith shared her personal opinion about DEI with The Institute, not as Princeton’s dean of engineering and applied sciences. A wireless communications pioneer, she is an IEEE Fellow who launched the IEEE Board of Directors Diversity and Inclusion Committee in 2019 and once served as its chair.

She received this year’s IEEE Mulligan Education Medal for educating, mentoring, and inspiring generations of students, and for authoring pioneering textbooks in advanced digital communications.

“For the longest time,” Goldsmith says, “there was so much positive momentum toward improving diversity and inclusion. And now there’s a backlash, which is really unfortunate, but it’s not everywhere.” She says she is proud of her university’s president, who has been vocal that diversity is about excellence and that Princeton is better because its students and faculty are diverse.

In the interview, Goldsmith spoke about why she thinks the topic has become so controversial, what measures universities can take to ensure their students have a sense of belonging, and what can be done to retain female engineers—a group that has been underrepresented in the field.

The Institute: What do you think is behind the movement to dissolve DEI programs?

Goldsmith: That’s a very complex question, and I certainly don’t have the answer.

It has become a politically charged issue because there’s a notion that DEI programs are really about quotas or advancing people who are not deserving of the positions they have been given. Part of the backlash also was spurred by the Oct. 7 attack on Israel, the war in Gaza, and the protests. One notion is that Jewish students are also a minority that needs protection, and why is it that DEI programs are only focused on certain segments of the population as opposed to diversity and inclusion for everyone, for people with all different perspectives, and those who are victims or subject to explicit bias, implicit bias, or discrimination? I think that these are legitimate concerns, and that programs around diversity and inclusion should be addressing them.

The goal of diversity and inclusion is that everybody should be able to participate and reach their full potential. That should go for every profession and, in particular, every segment of the engineering community.

Also in the middle of this backlash is the U.S. Supreme Court’s 2023 decision that ended race-conscious affirmative action in college admissions—which means that universities cannot take diversity into account explicitly in their admission of students. The decision in and of itself only affects undergraduate admissions, but it has raised concerns about broadening the decision to faculty hiring or for other kinds of programs that promote diversity and inclusion within universities and private companies.

I think the Supreme Court’s decision, along with the political polarization and the recent protests at universities, have all been pieces of a puzzle that have come together to paint all DEI programs with a broad brush of not being about excellence and lowering barriers but really being about promoting certain groups of people at the expense of others.

How might the elimination of DEI programs impact the engineering profession specifically?

Goldsmith: I think it depends on what it means to eliminate DEI programs. Programs to promote the diversity of ideas and perspectives in engineering are essential for the success of the profession. As an optimist, I believe we should continue to have programs that ensure our profession can bring in people with diverse perspectives and experiences.

Does that mean that every DEI program in engineering companies and universities needs to evolve or change? Not necessarily. Maybe some programs do because they aren’t necessarily achieving the goal of ensuring that diverse people can thrive.

“My work in the profession of engineering to enhance diversity and inclusion has really been about excellence for the profession.”

We need to be mindful of the concerns that have been raised about DEI programs. I don’t think they are completely unfounded.

If we do the easy thing—which is to just eliminate the programs without replacing them with something else or evolving them—then it will hurt the engineering profession.

The metrics being used to assess whether these programs are achieving their goals need to be reviewed. If they are not, the programs need to be improved. If we do that, I think DEI programs will continue to positively impact the engineering profession.

For universities that have cut or reduced their programs, what are some other ways to make sure all students have a sense of belonging?

Goldsmith: I would look at what other initiatives could be started that would have a different name but still have the goal of ensuring that students have a sense of belonging.

Long before DEI programs, there were other initiatives within universities that helped students figure out their place within the school, initiated them into what it means to be a member of the community, and created a sense of belonging through various activities. These include prefreshman and freshman orientation programs, student groups and organizations, student-led courses (with or without credit), eating clubs, fraternities, and sororities, to name just a few. I am referring here to any program within a university that creates a sense of community for those who participate—which is a pretty broad category of programs.

These continue, but they aren’t called DEI programs. They’ve been around for decades, if not since the university system was founded.

How can universities and companies ensure that all people have a good experience in school and the workplace?

Goldsmith: This year has been a huge challenge for universities, with protests, sit-ins, arrests, and violence.

One of the things I said in my opening remarks to freshmen at the start of this semester is that you will learn more from people around you who have different viewpoints and perspectives than you will from people who think like you. And that engaging with people who disagree with you in a respectful and scholarly way and being open to potentially changing your perspective will not only create a better community of scholars but also better prepare you for postgraduation life, where you may be interacting with a boss, coworkers, family, and friends who don’t agree with you.

Finding ways to engage with people who don’t agree with you is essential for engaging with the world in a positive way. I know we don’t think about that as much in engineering because we’re going about building our technologies, doing our equations, or developing our programs. But so much of engineering is collaboration and understanding other people, whether it’s your customers, your boss, or your collaborators.

I would argue everyone is diverse. There’s no such thing as a nondiverse person, because no two people have the exact same set of experiences. Figuring out how to engage with people who are different is essential for success in college, grad school, your career, and your life.

I think it’s a bit different in companies, because you can fire someone who does a sit-in in the boss’s office. You can’t do that in universities. But I think workplaces also need to create an environment where diverse people can engage with each other beyond just what they’re working on in a way that’s respectful and intellectual.

Reports show that half of female engineers leave the high-tech industry because they have a poor work experience. Why is that, and what can be done to retain women?

Goldsmith: That is one of the harder questions facing the engineering profession. The challenges that women face are implicit, including sometimes explicit bias. In extreme cases, there are sexual and other kinds of harassment, and bullying. These egregious behaviors have decreased some. The Me Too movement raised a lot of awareness, but [poor behavior] still is far more prevalent than we want it to be. It’s very difficult for women who have experienced that kind of egregious and illegal behavior to speak up. For example, if it’s their Ph.D. advisor, what does that mean if they speak up? Do they lose their funding? Do they lose all the research they’ve done? This powerful person can bad-mouth them for job applications and potential future opportunities.

So, it’s very difficult to curb these behaviors. However, there has been a lot of awareness raised, and universities and companies have put protections in place against them.

Then there’s implicit bias, where a qualified woman is passed over for a promotion, or women are asked to take meeting notes but not the men. Or a woman leader gets a bad performance review because she doesn’t take no for an answer, is too blunt, or too pushy. All these are things that male leaders are actually lauded for.

There is data on the barriers and challenges that women face and what universities and employers can do to mitigate them. These are the experiences that hurt women’s morale and upward mobility and, ultimately, make them leave the profession.

One of the most important things for a woman to be successful in this profession is to have mentors and supporters. So it is important to make sure that women engineers are assigned mentors at every stage, from student to senior faculty or engineer and everything in between, to help them understand the challenges they face and how to deal with them, as well as to promote and support them.

I also think having leaders in universities and companies recognize and articulate the importance of diversity helps set the tone from the top down and tends to mitigate some of the bias and implicit bias in people lower in the organization.

I think the backlash against DEI is going to make it harder for leaders to articulate the value of diversity, and to put in place some of the best practices around ensuring that diverse people are considered for positions and reach their full potential.

We have definitely taken a step backward in the past year on the understanding that diversity is about excellence and implementing best practices that we know work to mitigate the challenges that diverse people face. But that just means we need to redouble our efforts.

Although this isn’t the best time to be optimistic about diversity in engineering, if we take the long view, I think that things are certainly better than they were 20 or 30 years ago. And I think 20 or 30 years from now they’ll be even better.

Many U.S. university students returning to campus this month will find their school no longer has a diversity, equity, and inclusion program. More than 200 universities in 30 states so far this year have eliminated, cut back, or changed their DEI efforts, according to an article in The Chronicle of Higher Education.

It is happening at mostly publicly funded universities, because state legislators and governors are enacting laws that prohibit or defund DEI programs. They’re also cutting budgets and sometimes implementing other measures that restrict diversity efforts. Some colleges have closed their DEI programs altogether to avoid political pressure.

The Institute asked Andrea J. Goldsmith, a top educator and longtime proponent of diversity efforts within the engineering field and society, to weigh in.

Goldsmith shared her personal opinion about DEI with The Institute, not as Princeton’s dean of engineering and applied sciences. A wireless communications pioneer, she is an IEEE Fellow who launched the IEEE Board of Directors Diversity and Inclusion Committee in 2019 and once served as its chair.

She received this year’s IEEE Mulligan Education Medal for educating, mentoring, and inspiring generations of students, and for authoring pioneering textbooks in advanced digital communications.

“For the longest time,” Goldsmith says, “there was so much positive momentum toward improving diversity and inclusion. And now there’s a backlash, which is really unfortunate, but it’s not everywhere.” She says she is proud of her university’s president, who has been vocal that diversity is about excellence and that Princeton is better because its students and faculty are diverse.

In the interview, Goldsmith spoke about why she thinks the topic has become so controversial, what measures universities can take to ensure their students have a sense of belonging, and what can be done to retain female engineers—a group that has been underrepresented in the field.

The Institute: What do you think is behind the movement to dissolve DEI programs?

Goldsmith: That’s a very complex question, and I certainly don’t have the answer.

It has become a politically charged issue because there’s a notion that DEI programs are really about quotas or advancing people who are not deserving of the positions they have been given. Part of the backlash also was spurred by the Oct. 7 attack on Israel, the war in Gaza, and the protests. One notion is that Jewish students are also a minority that needs protection, and why is it that DEI programs are only focused on certain segments of the population as opposed to diversity and inclusion for everyone, for people with all different perspectives, and those who are victims or subject to explicit bias, implicit bias, or discrimination? I think that these are legitimate concerns, and that programs around diversity and inclusion should be addressing them.

The goal of diversity and inclusion is that everybody should be able to participate and reach their full potential. That should go for every profession and, in particular, every segment of the engineering community.

Also in the middle of this backlash is the U.S. Supreme Court’s 2023 decision that ended race-conscious affirmative action in college admissions—which means that universities cannot take diversity into account explicitly in their admission of students. The decision in and of itself only affects undergraduate admissions, but it has raised concerns about broadening the decision to faculty hiring or for other kinds of programs that promote diversity and inclusion within universities and private companies.

I think the Supreme Court’s decision, along with the political polarization and the recent protests at universities, have all been pieces of a puzzle that have come together to paint all DEI programs with a broad brush of not being about excellence and lowering barriers but really being about promoting certain groups of people at the expense of others.

How might the elimination of DEI programs impact the engineering profession specifically?

Goldsmith: I think it depends on what it means to eliminate DEI programs. Programs to promote the diversity of ideas and perspectives in engineering are essential for the success of the profession. As an optimist, I believe we should continue to have programs that ensure our profession can bring in people with diverse perspectives and experiences.

Does that mean that every DEI program in engineering companies and universities needs to evolve or change? Not necessarily. Maybe some programs do because they aren’t necessarily achieving the goal of ensuring that diverse people can thrive.

“My work in the profession of engineering to enhance diversity and inclusion has really been about excellence for the profession.”

We need to be mindful of the concerns that have been raised about DEI programs. I don’t think they are completely unfounded.

If we do the easy thing—which is to just eliminate the programs without replacing them with something else or evolving them—then it will hurt the engineering profession.

The metrics being used to assess whether these programs are achieving their goals need to be reviewed. If they are not, the programs need to be improved. If we do that, I think DEI programs will continue to positively impact the engineering profession.

For universities that have cut or reduced their programs, what are some other ways to make sure all students have a sense of belonging?

Goldsmith: I would look at what other initiatives could be started that would have a different name but still have the goal of ensuring that students have a sense of belonging.

Long before DEI programs, there were other initiatives within universities that helped students figure out their place within the school, initiated them into what it means to be a member of the community, and created a sense of belonging through various activities. These include prefreshman and freshman orientation programs, student groups and organizations, student-led courses (with or without credit), eating clubs, fraternities, and sororities, to name just a few. I am referring here to any program within a university that creates a sense of community for those who participate—which is a pretty broad category of programs

These continue, but they aren’t called DEI programs. They’ve been around for decades, if not since the university system was founded.

How can universities and companies ensure that all people have a good experience in school and the workplace?

Goldsmith: This year has been a huge challenge for universities, with protests, sit-ins, arrests, and violence.

One of the things I said in my opening remarks to freshmen at the start of this semester is that you will learn more from people around you who have different viewpoints and perspectives than you will from people who think like you. And that engaging with people who disagree with you in a respectful and scholarly way and being open to potentially changing your perspective will not only create a better community of scholars but also better prepare you for postgraduation life, where you may be interacting with a boss, coworkers, family, and friends who don’t agree with you.

Finding ways to engage with people who don’t agree with you is essential for engaging with the world in a positive way. I know we don’t think about that as much in engineering because we’re going about building our technologies, doing our equations, or developing our programs. But so much of engineering is collaboration and understanding other people, whether it’s your customers, your boss, or your collaborators.

I would argue everyone is diverse. There’s no such thing as a nondiverse person, because no two people have the exact same set of experiences. Figuring out how to engage with people who are different is essential for success in college, grad school, your career, and your life.

I think it’s a bit different in companies, because you can fire someone who does a sit-in in the boss’s office. You can’t do that in universities. But I think workplaces also need to create an environment where diverse people can engage with each other beyond just what they’re working on in a way that’s respectful and intellectual.

Reports show that half of female engineers leave the high-tech industry because they have a poor work experience. Why is that, and what can be done to retain women?

Goldsmith: That is one of the harder questions facing the engineering profession. The challenges that women face are implicit, including sometimes explicit bias. In extreme cases, there are sexual and other kinds of harassment, and bullying. These egregious behaviors have decreased some. The Me Too movement raised a lot of awareness, but [poor behavior] still is far more prevalent than we want it to be. It’s very difficult for women who have experienced that kind of egregious and illegal behavior to speak up. For example, if it’s their Ph.D. advisor, what does that mean if they speak up? Do they lose their funding? Do they lose all the research they’ve done? This powerful person can bad-mouth them for job applications and potential future opportunities.

So, it’s very difficult to curb these behaviors. However, there has been a lot of awareness raised, and universities and companies have put protections in place against them.

Then there’s implicit bias, where a qualified woman is passed over for a promotion, or women are asked to take meeting notes but not the men. Or a woman leader gets a bad performance review because she doesn’t take no for an answer, is too blunt, or too pushy. All these are things that male leaders are actually lauded for.

There is data on the barriers and challenges that women face and what universities and employers can do to mitigate them. These are the experiences that hurt women’s morale and upward mobility and, ultimately, make them leave the profession.

One of the most important things for a woman to be successful in this profession is to have mentors and supporters. So it is important to make sure that women engineers are assigned mentors at every stage, from student to senior faculty or engineer and everything in between, to help them understand the challenges they face and how to deal with them, as well as to promote and support them.

I also think having leaders in universities and companies recognize and articulate the importance of diversity helps set the tone from the top down and tends to mitigate some of the bias and implicit bias in people lower in the organization.

I think the backlash against DEI is going to make it harder for leaders to articulate the value of diversity, and to put in place some of the best practices around ensuring that diverse people are considered for positions and reach their full potential.

We have definitely taken a step backward in the past year on the understanding that diversity is about excellence and implementing best practices that we know work to mitigate the challenges that diverse people face. But that just means we need to redouble our efforts.

Although this isn’t the best time to be optimistic about diversity in engineering, if we take the long view, I think that things are certainly better than they were 20 or 30 years ago. And I think 20 or 30 years from now they’ll be even better.

Sharlene Brown often accompanied her husband, IEEE Senior Member Damith Wickramanayake, to organization meetings. He has held leadership positions in the IEEE Jamaica Section, in IEEE Region 3, and on the IEEE Member and Geographic Activities board. Both are from Jamaica.

She either waited outside the conference room or helped with tasks such as serving refreshments. Even though her husband encouraged her to sit in on the meetings, she says, she felt uncomfortable doing so because she wasn’t an engineer. Brown is an accountant and human resources professional. Her husband is a computer science professor at the University of Technology, Jamaica, in Kingston. He is currently Region 3’s education activities coordinator and a member of the section’s education and outreach committee for the IEEE Educational Activities Board.

Sharlene Brown

Employer

Maritime Authority of Jamaica, in Kingston

Title

Assistant accountant

Member grade

Senior member

Alma mater

University of Technology, Jamaica, in Kingston; Tsinghua University, in Beijing

After earning her master’s degree in public administration in 2017, Brown says, she felt she finally was qualified to join IEEE, so she applied. Membership is open to individuals who, by education or experience, are competent in different fields including management. She was approved the same year.

“When I joined IEEE, I would spend long hours at night reading various operations manuals and policies because I wanted to know what I was getting into,” she says. “I was always learning. That’s how I got to know a lot of things about the organization.”

Brown is now a senior member and an active IEEE volunteer. She founded the Jamaica Section’s Women in Engineering group; established a student branch; sits on several high-level IEEE boards; and ran several successful recruitment campaigns to increase the number of senior members in Jamaica and throughout Region 3.

Brown was also a member of the subcommittee of the global Women in Engineering committee; she served as membership coordinator and ran several successful senior member campaigns, elevating women on the committee and across IEEE.

Brown also was integral in the promotion and follow-up activities for the One IEEE event held in January at the University of Technology, Jamaica. The first-of-its-kind workshop connected more than 200 participants to each other and to the organization by showcasing Jamaica’s active engineering community. The Jamaica Section has 135 IEEE members.

From factory worker to accountant

Brown grew up in Bog Walk, a rural town in the parish of St. Catherine. Because she had low grades in high school, the only job she was able to get after graduating was as a temporary factory worker at the nearby Nestlé plant. She worked as many shifts as she could to help support her family.

“I didn’t mind working,” she says, “because I was making my mark. Anything I do, I am going to be excellent at, whether it’s cleaning the floor or doing office work.” But she had bigger plans than being a factory worker, she says.

A friend told her about a temporary job overseeing exams at the Jamaican Institute of Management, now part of the University of Technology. Brown worked both jobs for a time until the school hired her full time to do administrative work in its accounting department.

One of the perks of working there was free tuition for employees, and Brown took full advantage. She studied information management and computer applications, Jamaican securities, fraud detection, forensic auditing, and supervisory management, earning an associate degree in business administration in 2007. The school hired her in 2002 as an accountant, and she worked there for five years.

In 2007 she joined the Office of the Prime Minister, in Kingston, initially as an officer handling payments to suppliers. Her hard work and positive attitude got her noticed by other managers, she says. After a month she was tapped by the budget department to become a commitment control officer, responsible for allocating and overseeing funding for four of the country’s ministries.

“What I realized through my volunteer work in IEEE is that you’re never alone. There is always somebody to guide you.”

As a young accountant, she didn’t have hands-on experience with budgeting, but she was a quick learner who produced quality work, she says. She learned the budgeting process by helping her colleagues when her work slowed down and during her lunch breaks.

That knowledge gave her the skills she needed to land her current job as an assistant accountant with the budget and management accounts group in the Maritime Authority of Jamaica accounts department, a position she has held since 2013.

While she was working for the Office of the Prime Minister, Brown continued to further her education. She took night courses at the University of Technology and, in 2012, earned a bachelor’s degree in business administration. She majored in accounting and minored in human resources management.

She secured a full scholarship in 2016 from the Chinese government to study public administration in Beijing at Tsinghua University, earning a master’s degree with distinction in 2017.

Brown says she is now ready to shift to a human resources career. Even though she has been supervising people for more than 17 years, though, she is having a hard time finding an HR position, she says.

Still willing to take on challenges, she is increasing her experience by volunteering with an HR consulting firm in Jamaica. To get more formal training, she is currently working on an HR certification from the Society for Human Resource Management.

Sharlene Brown arranged for the purchase of 350 desk shields for Jamaican schools during the COVID-19 pandemic.Sharlene Brown

Building a vibrant community

After graduating from Tsinghua University, Brown began volunteering for the IEEE Jamaica Section and Region 3.

In 2019 she founded the section’s IEEE Women in Engineering affinity group, which she chaired for three years. She advocated for more women in leadership roles and has run successful campaigns to increase the number of female senior members locally, regionally, and globally across IEEE. She herself was elevated to senior member in 2019.

Brown also got the WIE group more involved in helping the community. One project she is particularly proud of is the purchase of 350 desk shields for Jamaican schools so students could more safely attend classes and examination sessions in person during the COVID-19 pandemic.

Brown was inspired to undertake the project when a student explained on a local news program that his family couldn’t afford Internet for their home, so he was unable to attend classes remotely.

“Every time I watched the video clip, I would cry,” she says. “This young man might be the next engineer, the country’s next minister, or the next professional.

“I’m so happy we were able to get funding from Region 3 and a local organization to provide those shields.”

She established an IEEE student branch at the Caribbean Maritime University, in Kingston. The branch had almost 40 students at the time of formation.

Brown is working to form student branches at other Jamaican universities, and she is attempting to establish an IEEE Power & Energy Society chapter in the section.

She is a member of several IEEE committees including the Election Oversight and Tellers. She serves as chair for the region’s Professional Activities Committee.

“What I realized through my volunteer work in IEEE is that you’re never alone,” she says. “There is always somebody to help guide you. If they don’t know something, they will point you to the person who does.

“Also, you’re allowed to make mistakes,” she says. “In some organizations, if you make a mistake, you might lose your job or have to pay for your error. But IEEE is your professional home, where you learn, grow, and make mistakes.”

On some of the IEEE committees where she serves, she is the only woman of color, but she says she has not faced any discrimination—only respect.

“I feel comfortable and appreciated by the people and the communities I work with,” she says. “That motivates me to continue to do well and to touch lives positively. That’s what makes me so active in serving in IEEE: You’re appreciated and rewarded for your hard work.”

Telecom engineers and researchers face several challenges when it comes to testing their 5G and 6G prototypes. One is finding a testbed where they can run experiments with their new hardware and software.

The experimentation platforms, which resemble real-world conditions, can be pricey. Some have a time limit. Others may be used only by specific companies or for testing certain technologies.

The new IEEE 5G/6G Innovation Testbed has eliminated many of those barriers. Built by IEEE, the platform is for those who want to try out their 5G enhancements, run trials of future 6G functions, or test updates for converged networks. Users may test and retest as many times as they want at no additional cost.

Telecom operators can use the new virtual testbed, as can application developers, researchers, educators, and vendors from any industry.

“The IEEE 5G/6G Innovation Testbed creates an environment where industry can break new ground and work together to develop the next generation of technology innovations,” says Anwer Al-Dulaimi, cochair of the IEEE 5G/6G Innovation Testbed working group. Al-Dulaimi, an IEEE senior member, is a senior strategy manager of connectivity and Industry 4.0 for Veltris, in Toronto.

The testbed was launched this year with support from AT&T, Exfo, Eurecom, Veltris, VMWare, and Tech Mahindra.

The subscription-based testbed is available only to organizations. Customers receive their own private, secure session of the testing platform in the cloud along with the ability to add new users.

A variety of architectures and experiments

The platform eliminates the need for customers to travel to a location and connect to physical hardware, Al-Dulaimi says. That’s because its digital hub is based in the cloud, allowing companies, research facilities, and organizations to access it. The testbed allows customers to upload their own software components for testing.

“IEEE 5G/6G Innovation Testbed provides a unique platform for the service providers, and various vertical industries—including defense, homeland security, agriculture, and automotive—to experiment various use cases that can take advantage of advanced 5G technologies like ultra low latency, machine-to-machine type communications and massive broadband to help solve their pain points,” says IEEE Fellow Ashutosh Dutta, who is a cochair of the working group. Dutta works as chief 5G strategist at the Johns Hopkins University Applied Physics Laboratory, in Laurel, Md. He also heads the university’s Doctor of Engineering program.

“The IEEE 5G/6G Innovation Testbed creates an environment where industry can break new ground and work together to develop the next generation of technology innovations.”

The collaborative, secure, cloud-based platform also can emulate a 5G end-to-end network within the 3rd Generation Partnership Program (3GPP), which defines cellular communications standards.

“Companies can use the platform for testing, but they can also use the environment as a virtual hands-on showcase of new products, services, and network functions,” Dutta says.

In addition to the cloud-based end-to-end environment, the testbed supports other architectures including multiaccess edge computing for reduced latency, physical layer testing via 5G access points and phones installed at IEEE, and Open RAN (radio access network) environments where wireless radio functionality is disaggregated to allow for better flexibility in mixing hardware and software components.

A variety of experiments can be conducted, Al-Dulaimi says, including:

• Voice and video call emulation.
• Authentication and encryption impact evaluation across different 5G platforms.
• Network slicing.
• Denial-of-service attacks and interoperability and overload incidents.
• Verifying the functionality, compatibility, and interoperability of products.
• Assessing conformity of networks, components, and products.

The testbed group plans to release a new graphical user interface soon, as well as a test orchestration tool that contains hundreds of plug-and-play test cases to help customers quickly determine if their prototypes are working as intended across a variety of standards and scenarios. In addition to basic “sanity testing,” it includes tools to measure a proposed product’s real-time performance.

The proofs of concept—lessons learned from experiments—will help advance existing standards and create new ones, Dutta says, and they will expedite the deployment of 5G and 6G technologies.

The IEEE 5G/6G testbed is an asset that can be used by the academics, researchers, and R&D labs, he says, to help “close the gap between theory and practice. Students across the world can take advantage of this testbed to get hands-on experience as part of their course curriculum.”

Partnership with major telecom companies

The IEEE 5G/6G Innovation Testbed recently joined the Acceleration of Compatibility and Commercialization for Open RAN Deployments project. A public-private consortium, ACCORD includes AT&T, Verizon, Virginia Tech and the University of Texas at Dallas. The group is funded by the U.S. Department of Commerce’s National Telecommunications and Information Administration, whose programs and policymaking efforts focus on expanding broadband Internet access and adoption throughout the country.

“The 3GPP-compliant end-to-end 5G network is built with a suite of open-source modules, allowing companies to customize the network architecture and tailor their testbed environment according to their needs,” Al-Dulaimi says.

The testbed was made possible with a grant from the IEEE New Initiatives Committee, which funds potential IEEE services, products, and other creations that could significantly benefit members, the public, customers, or the technical community.

Watch this short demonstration of how the IEEE 5G/6G Innovation Testbed works. youtube