“It’s a lot to listen to a robot all day long,” said Tina Pinedo, communications director at Disability Rights Oregon, a group that works to promote and defend the rights of people with disabilities.
But listening to a machine is exactly what many people with visual impairments do while using screen reading tools to accomplish everyday online tasks such as paying bills or ordering groceries from an ecommerce site.
“There are not enough web developers or people who actually take the time to listen to what their website sounds like to a blind person. It’s auditorily exhausting,” said Pinedo.
Whether struggling to comprehend a screen reader barking out dynamic updates to a website, trying to make sense of poorly written video captions or watching out for fast-moving imagery that could induce a seizure, the everyday obstacles blocking people with disabilities from a satisfying digital experience are immense.
Needless to say, technology companies have tried to step in, often promising more than they deliver to users and businesses hoping that automated tools can break down barriers to accessibility. Although automated tech used to check website designs for accessibility flaws have been around for some time, companies such as Evinced claim that sophisticated AI not only does a better job of automatically finding and helping correct accessibility problems, but can do it for large enterprises that need to manage thousands of website pages and app content.
Still, people with disabilities and those who regularly test for web accessibility problems say automated systems and AI can only go so far. “The big danger is thinking that some type of automation can replace a real person going through your website, and basically denying people of their experience on your website, and that’s a big problem,” Pinedo said.
Why Capital One is betting on accessibility AI
For a global corporation such as Capital One, relying on a manual process to catch accessibility issues is a losing battle.
“We test our entire digital footprint every month. That’s heavily reliant on automation as we’re testing almost 20,000 webpages,” said Mark Penicook, director of Accessibility at the banking and credit card company, whose digital accessibility team is responsible for all digital experiences across Capital One including websites, mobile apps and electronic messaging in the U.S., the U.K. and Canada.
Accessibility isn’t taught in computer science.
Even though Capital One has a team of people dedicated to the effort, Penicook said he has had to work to raise awareness about digital accessibility among the company’s web developers. “Accessibility isn’t taught in computer science,” Penicook told Protocol. “One of the first things that we do is start teaching them about accessibility.”
One way the company does that is by celebrating Global Accessibility Awareness Day each year, Penicook said. Held on Thursday, the annual worldwide event is intended to educate people about digital access and inclusion for those with disabilities and impairments.
Before Capital One gave Evinced’s software a try around 2018, its accessibility evaluations for new software releases or features relied on manual review and other tools. Using Evinced’s software, Penicook said the financial services company’s accessibility testing takes hours rather than weeks, and Capital One’s engineers and developers use the system throughout their internal software development testing process.
It was enough to convince Capital One to invest in Evinced through its venture arm, Capital One Ventures. Microsoft’s venture group, M12, also joined a $17 million funding round for Evinced last year.
Evinced’s software automatically scans webpages and other content, and then applies computer vision and visual analysis AI to detect problems. The software might discover a lack of contrast between font and background colors that make it difficult for people with vision impairments like color blindness to read. The system might find images that do not have alt text, the metadata that screen readers use to explain what’s in a photo or illustration. Rather than pointing out individual problems, the software uses machine learning to find patterns that indicate when the same type of problem is happening in several places and suggests a way to correct it.
“It automatically tells you, instead of a thousand issues, it’s actually one issue,” said Navin Thadani, co-founder and CEO of Evinced.
The software also takes context into account, factoring in the purpose of a site feature or considering the various operating systems or screen-reader technologies that people might use when visiting a webpage or other content. For instance, it identifies user design features that might be most accessible for a specific purpose, such as a button to enable a bill payment transaction rather than a link.
Some companies use tools typically referred to as “overlays” to check for accessibility problems. Many of those systems are web plug-ins that add a layer of automation on top of existing sites to enable modifications tailored to peoples’ specific requirements. One product that uses computer vision and machine learning, accessiBe, allows people with epilepsy to choose an option that automatically stops all animated images and videos on a site before they could pose a risk of seizure. The company raised $28 million in venture capital funding last year.
Another widget from TruAbilities offers an option that limits distracting page elements to allow people with neurodevelopmental disorders to focus on the most important components of a webpage.
Some overlay tools have been heavily criticized for adding new annoyances to the web experience and providing surface-level responses to problems that deserve more robust solutions. Some overlay tech providers have “pretty brazen guarantees,” said Chase Aucoin, chief architect at TPGi, a company that provides accessibility automation tools and consultation services to customers, including software development monitoring and product design assessments for web development teams.
“[Overlays] give a false sense of security from a risk perspective to the end user,” said Aucoin, who himself experiences motor impairment. “It’s just trying to slap a bunch of paint on top of the problem.”
In general, complicated site designs or interfaces that automatically hop to a new page section or open a new window can create a chaotic experience for people using screen readers, Aucoin said. “A big thing now is just cognitive; how hard is this thing for somebody to understand what’s going on?” he said.
Even more sophisticated AI-based accessibility technologies don’t address every disability issue. For instance, people with an array of disabilities either need or prefer to view videos with captions, rather than having sound enabled. However, although automated captions for videos have improved over the years, “captions that are computer-generated without human review can be really terrible,” said Karawynn Long, an autistic writer with central auditory processing disorder and hyperlexia, a hyperfocus on written language.
“I always appreciate when written transcripts are included as an option, but auto-generated ones fall woefully short, especially because they don’t include good indications of non-linguistic elements of the media,” Long said.
Climate change is an issue that affects everyone on the planet but women and girls are the ones suffering its effects the most. Why? Because women and girls have less access to quality education and later, job opportunities. These structural disadvantages keep them in poverty. In fact, women make up 70% of the world’s poor. In a nutshell, climate change impacts the poor the most and the poor are mostly women.
Poverty driven by and made worse by climate change also makes girls more susceptible to child marriage, because it drives hunger and girls getting married often means one less mouth to feed for their parents. Climate change also leads to geopolitical instability which, in turn, results in greater instances of violence — which we know disproportionately impacts women and girls.
Ironically, saving the planet has been made to seem a “women’s job”. This phenomenon, dubbed the “eco gender gap”, sees the burden of climate responsibility placed squarely on women’s shoulders through “green” campaigns and products that are overwhelmingly marketed to women.
There are several hypotheses for why this is. Firstly, women are the more powerful consumers (they drive 70-80% of all purchasing decisions). Secondly, they are disproportionately responsible, still, for the domestic sphere. And finally, going green is seen as a women’s job because women’s personalities are supposedly more nurturing and socially responsible.
Women should be involved in fighting the climate crisis at every level — from the kitchen to the science lab to the boardroom. Ruth Bader Ginsburg explained it best when she said: “Women belong in all places where decisions are being made.” However, women are underrepresented in the science field (including climate science), with just 30% of research positions held by women and fewer still holding senior positions. The Reuters Hot List of 1,000 scientists features just 122 women.
Having more women climate scientists could allow for an increased emphasis on understanding and providing solutions for some of the most far-reaching implications of climate change. Diversity in background and experiences allows for different perspectives. More perspectives allow for different research questions to arise or even a different approach to the same question.
There are, however, women all over the world in the fields of science, technology, engineering, and mathematics (STEM) that have made some incredible strides in the fight against the climate crisis, from fire-resistant coating to protect places prone to wildfires, to a water-storing park for a region usually overwhelmed by floods. Here are just some of the world’s incredible women scientists leading the way on tackling the climate crisis.
Click here to read the full article on Global Citizen.
As 2023 has arrived, you may be looking to take the next big step in your STEM education journey. While specific needs will differ from person to person, knowing which schools are the best for a STEM education can be a great start.
Here are the top STEM schools of the last year:
Massachusetts Institute of Technology: The Massachusetts Institute of Technology, most popularly referred to as MIT, is a private land-grant research university. The school is best known for its key role in the development of modern technology and science.
Location: Cambridge, Massachusetts
Average Tuition: $74,500 without grants, $21,100 with grants
Acceptance Rate: 7%
Graduation Rate: 94%
Notable Alumni: Apollo 11 Astronaut: Buzz Aldrin; Economics Nobel laureate: Esther Duflo; CEO of General Motors: Alfred P. Sloan
Georgia Institute of Technology: The Georgia Institute of Technology, commonly referred to as Georgia Tech, is a public research university and institute of technology. Their specialty is in science and technology, but they are additionally recognized as an elite institution for computer science, engineering and business.
Location: Atlanta, Georgia
Average Tuition: $30,600 without grants, $18,400 with grants
Acceptance Rate: 21%
Graduation Rate: 87%
Notable Alumni: President Jimmy Carter; Nobel Prize in Chemistry Winner: Kary Mullis; CEO of Earthlink: Charles “Garry” Betty
California Institute of Technology: The California Institute of Technology, also known as Caltech, is a private research university known for its specialties in science and engineering. Caltech is ranked among the best academic institutions in the world and is among the most selective in the U.S.
Location: Pasadena, California
Average Tuition: $79,900 without grants, $28,100 with grants
Acceptance Rate: 6%
Graduation Rate: 92%
Notable Alumni: Father of Silicon Valley: William Shockley; Co-founder of JPL: Qian Xuesen; Director of NSF: France A. Córdova
Harvey Mudd College: Harvey Mudd College is an American private college in Claremont, California focused on science and engineering. The school produces graduates who earn the highest mid-career salaries of any college or university in the country.
Location: Claremont, California
Average Tuition: $81,800 without grants, $39,300 with grants
Acceptance Rate: 14%
Graduation Rate: 92%
Notable Alumni: Co-inventor of SQL: Donald D. Chamberlain; Former US Ambassador to Israel: Richard H. Jones; Esports commentator and game designer: Sean “Day9” Plott
Stanford University: Stanford University is a private research university and one of the top-ranking universities in the world. Though they have many specialties, they are known for their graduate programs in law, medicine, education and business.
Location: Stanford, California
Average Tuition: $80,400 without grants, $21,100 with grants
Acceptance Rate: 4%
Graduation Rate: 94%
Notable Alumni: President John F. Kennedy; Astronaut Mae Jemison; Co-creator of the internet: Vint Cerf
University of California, Berkeley: A founding member of the Association of American Universities, UC Berkeley is a public land-grant research university. As one of the top universities in the country, Berkley hosts many leading research institutes dedicated to science, engineering and mathematics.
Location: Berkeley, California
Average Tuition: $42,700 without grants, $20,400 with grants
Acceptance Rate: 16%
Graduation Rate: 92%
Notable Alumni: Co-founder of Apple Computer: Steve Wozniak; Astronaut Leroy Chiao; Nobel laureate in Physics and former Secretary of Energy: Steven Chu
University of California, San Diego: UC San Diego is a public land-grant research university specializing in medicine and oceanography. The school is home to the region’s only academic health system, UC San Diego Health.
Location: La Jolla, California
Average Tuition: $36,300 without grants, $16,100 with grants
Acceptance Rate: 31%
Graduation Rate: 86%
Notable Alumni: Philanthropist and GoPro Founder: Nick Woodman; Nobel Prize Winner in Medicine: Susumu Tonegawa; Professor and Political Activist: Angela Davis
Texas A&M University-College Station: Texas A&M is a public land-grant research university and senior military college. They are home to one of the largest student bodies in the United States and hold simultaneous designations as a land, sea and space grant institution.
Location: College Station, Texas
Average Tuition: $32,300 without grants, $21,000 with grants
Acceptance Rate: 58%
Graduation Rate: 82%
Notable Alumni: Former US Secretary of Energy: Ricky Perry; Mechanical engineer and first woman to be chief flight director at NASA: Holly Ridings; CEO of U.S. Wal-Mart Stores: Eduardo Castro-Wright
University of Illinois at Urbana-Champaign: The University of Illinois Urbana-Champaign, or UIUC for short, is a public land-grant research university. Besides producing several Nobel laureates and Pulitzer Prize winners, UIUC is home to the second-largest university library in the country and the fastest supercomputer on a university campus. They are also home to Research Park, an innovation center for some of the biggest start-ups and corporations in the country.
Location: Champaign, Illinois
Average Tuition: $32,000 without grants, $14,300 with grants
Acceptance Rate: 59%
Graduation Rate: 84%
Notable Alumni: Double Nobel prize winner in Physics: John Bardeen; Paypal Creator: Max Levchin; YouTube Founders: Steve Chen and Jawed Karim
University of Michigan: The University of Michigan is a public research university consisting of nineteen colleges and degrees in 250 disciplines. They specialize in architecture and urban planning, business, medicine, law, public policy, pharmacy, social work, public health and dentistry. The school has produced over 250 high-level government officials such as senators, cabinet secretaries and governors.
Location: Ann Arbor, Michigan
Average Tuition: $32,000 without grants, $14,300 with grants
Acceptance Rate: 23%
Graduation Rate: 92%
Notable Alumni: Former United States Secretary of Agriculture: Julius Sterling Morton; Boeing co-founder: Edgar Nathaniel Gott; Founder of the Swarm Corporation and “Father of Artificial Life”: Chris Langton
Sources: Money.com, College Avenue Student Loans, Wikipedia
Daleele Alison likes to help others stop wasting time doing tasks that don’t provide direct value to their clients. He is a technology professional, entrepreneur and the CEO and co-founder of RooksDM, a technology consulting group that helps alleviate pain points for small to midsize companies by using the right technology. Alison has worked as a consultant, business analyst and project manager for Fortune 500 companies to SMBs.
Diversity in STEAM Magazine (DISM) spoke with Alison about his company, the role diversity plays in tech and more on his participation in NMSDC’s Emerging Young Entrepreneurs cohort.
DISM: What have you seen businesses struggle with the most when it comes to their technology? How does RooksDM help them?
Daleele Alison: From our perspective, businesses are excited about adopting new technology. However, when businesses rapidly implement new technology to fix a singular problem, this often becomes a band-aid solution and can lead to a different set of challenges. Many businesses end up with a large number of tech tools that become overwhelming to manage and lead to low user adoption. It’s important for businesses to take a step back and be strategic. At RooksDM, we ask the right questions about technology and processes and dig deep into the core pain points. Rather than simply throwing technology at a problem, we take a holistic approach. Our goal is to implement technology that works together and sets a foundation for scalable growth.
DISM: Do you feel there is diversity within the IT/tech sectors? Why or why not?
Alison: We have seen progress in diversity within the tech industry. Organizations with targeted initiatives to increase diversity have definitely started to move the needle. It’s exciting to see a shift in the industry, however, there is still a long way to go. It continues to be a challenge for diverse vendors to break into large enterprise corporations. I’m hopeful that through tracking and monitoring vendor diversity, we will see even greater progress in supporting minorities in tech.
DISM:Why was it important for you to participate in NMSDC’s (National Minority Supplier Development Council) Emerging Young Entrepreneurs cohort? What have you learned thus far that is applicable to your own business?
Alison: The NMSDC’s Emerging Young Entrepreneurs has been an important way for us to learn and network. Through this initiative, we have been able to connect with like-minded colleagues, which has led to advice and potential business growth. The sessions have been invaluable and have expanded my thoughts around marketing, finance and strategy. We are truly grateful to be a part of this community and are looking forward to more opportunities in the future.
DISM: How has being MBE certified through NMSDC leveraged your business’s success?
Alison: Being MBE certified through NMSDC has given RooksDM access to a much larger community of like-minded businesses. We now have exposure to larger organizations to build our business. We have also built relationships with fellow minority-owned businesses. It has been so valuable to learn from each other and share stories and resources that support business growth. We are also proud to share our certification with current and prospective clients. This certification provides us with additional credibility that supports our conversations with potential clients.
DISM:What advice would you give another minority-owned entrepreneur or business owner just getting started?
Alison: My advice to fellow minority owners is to be intentional about how you spend your time. It’s easy to focus on initiatives that don’t matter or that won’t make an impact. It is critical to have the right people in your network to lean on so you can spend your time where it matters most. For us, spending time building relationships has been a game changer, not just in nurturing prospects but also in strengthening relationships within our industry. Leaning on others in the industry for support and expertise has not only led to referrals but been helpful to our overall growth.
Implementing clean energy is far from just a phase, it’s a necessity. Given the growing concern with the climate crisis; scientists and innovators from across the country are working together to power our daily lives through environmentally friendly means. By joining a career in clean energy, you could not only aid in these efforts, but do so while securing a stable, growing career.
Here are five reasons why you should consider the clean energy workforce:
It’s a Growing Field in Every Way
We all know that clean energy is popular on a societal standpoint, but even economically the field is thriving. In late 2021, President Biden passed the Bipartisan Infrastructure Law, which among other things invested $65 billion in support for clean energy infrastructure, research, jobs and much more. More recently, the CHIPS and Science Act, as well as the new Inflation Reduction Act, have added billions in investments for clean energy jobs and technologies. This makes the salaries of those in Renewable energy higher than average.
Along with being incredibly well funded and well equipped for hiring, the industry also has a lot of opportunities for advancement. Since the industry is relatively new, many clean energy sectors look to promote within their current employees.
The Job Types are Endless
When we think of jobs in renewable energy, we tend to think of scientists, engineers and even construction workers. While all of these areas of expertise are looking for jobs, you don’t have to wear a lab coat or a hardhat to join the field. In fact, you can come from just about any background and find a career in energy that will work for you. For example, the Department of Energy hires for positions in an extensive list of positions including:
It is never too late or too difficult to join the clean energy workforce, and there are so many different ways in which you can apply your skills.
The Work Environment
As an often well-funded and new career industry, the clean energy sector tends to do a better job at keeping up with current business trends and creating a thriving work culture. This allows for many of the employees in the field to be positive and passionate about their work. Benefits of the work environment of the clean energy sector can include:
Fantastic diversity and inclusion initiatives in every sector
Health care benefits
Working with passionate, like-minded coworkers
Opportunities to work in-office or from home
Opportunities for creativity, innovation and collaboration
You’re Making a Difference
There are many reasons to work toward a clean energy future. Whether it’s to protect the environment, promote energy justice, secure national energy independence, make scientific advancements or lower energy costs, there are many moral reasons you may have for wanting to join the field. In some industries, it can be difficult to see how any of the work you’re doing is making a difference in the world, but the clean energy industry does the exact opposite. In clean energy, no matter what your part is, your field is working to literally change the world every day by fighting climate change and promoting a healthier world for generations to come.
As 2022 comes to a close and the New Years’ resolutions start to flow, you may have “Pursue a New Career” as one of your 2023 goals.
The STEM field is growing now more than ever with jobs in every sector of science, technology, engineering, arts and design and mathematics. Here are the top jobs in the STEM field going into the new year:
Bioengineers and Biomedical Engineers
Bioengineers and biomedical engineers combine engineering principles with sciences to design and create equipment, devices, computer systems and software. They are usually responsible for designing and operating medical equipment and devices such as artificial organs, prosthetic limbs and diagnostic technology. The bioengineering field is one of the highest “in-demand” jobs currently. They are currently estimated to grow at about 10 percent, a much higher rate than average.
Education: Bioengineers and biomedical engineers typically need a bachelor’s degree in bioengineering, biomedical engineering or a related engineering field. Some positions require a graduate degree.
Top States of Employment: California, Illinois, Massachusetts, Minnesota and Texas
Average Pay: $97,410 per year
Physicists study the interactions of matter and energy. Theoretical physicists and (including astronomers) may study the nature of time or the origin of the universe. They typically work on research teams to conduct research and experiments about the natural world, but they also work to design and create lasers, telescopes and other scientific equipment that will aid them in their research. Not only are jobs in this field in high demand, growing at about 8 percent, but are one of the highest paid jobs in the STEM field today.
Education: Physicists and astronomers typically need a Ph.D. for jobs in research and academia. However, physicist jobs in the federal government typically require a bachelor’s degree in physics.
Top States of Employment: California, Colorado, Maryland, New York and Virginia
Average Pay: $147,450 per year
Computer and Research Information Scientists
Computer and information research scientists design innovative uses for new and existing technology. They study and solve complex problems in computing for business, science, medicine etc. and have a profound knowledge in programming, complex algorithms and robotics. Many of their day-to-day tasks consist of research, computer work, team collaboration and experimentation. Jobs are growing at a little over four times the normal rate compared to average, with a whopping 21 percent increase.
Education: Computer and information research scientists typically need a master’s or higher degree in computer science or a related field, such as computer engineering. For federal government jobs, a bachelor’s degree may be sufficient for certain positions.
Top States of Employment: California, Maryland, Texas, Virginia and Washington
Average Pay: $131, 490 per year
Software developers create the computer applications that allow users to do specific tasks and the underlying systems that run the devices or control networks. They typically work with cliental to assess the company’s current programming and computer systems and work to create systems that are more efficient and helpful to their needs. They can also be responsible for the creation, development and functionality of computer programs and systems. Software development is a rapidly growing industry with a 25 percent outlook.
Education: Software developers typically only need a bachelor’s degree to work in the field.
Top States of Employment: California, New York, Texas, Virginia and Washington
Average Pay: $109, 020 per year
Information Security Analysts
Information security analysts plan and carry out security measures to protect an organization’s computer networks and systems. They are heavily involved with creating their organization’s disaster recovery plan, maintaining software, monitoring networks and fixing potential and confirmed program threats. They must also keep up to date on the latest news and developments surrounding the tech field. IT Analysts are one of the fastest growing fields in the STEM field at 35 percent.
Education: Information security analysts typically need a bachelor’s degree in a computer science field, along with related work experience. Employers may prefer to hire analysts who have professional certification.
Top States of Employment: Florida, Maryland, New York, Texas and Virginia
Average Pay: $102, 600 per year
Sources: Bureau of Labor Statistics, Oak Ridge Institute for Science and Education, NBC
In late September, Space-X Crew, the fifth crewed operational NASA Commercial Crew flight of a Crew Dragon spacecraft, and the eighth overall crewed orbital flight launched into the cosmos and traveled to the space station. But unlike any other space mission in history, this one was led by mission commander Nicole Aunapu Mann, a colonel for the U.S. Marines, the first woman commander of a NASA Commercial Crew Program launch, and the first Native American woman in space.
Before ever setting foot in NASA territory, Mann attended the U.S. Naval Academy for her undergraduate degree and Stanford University for her graduate degree, both of which were in mechanical engineering. Mann was commissioned as a second lieutenant in the United States Marine Corps in 1999, completed flight training at The Basic School in Quantico in 2001, and began her operational flying career with her wings of gold as Naval Aviator by 2004. During this assignment, she deployed twice with CVW-1 aboard the USS Enterprise and flew combat missions in support of Operations IRAQI FREEDOM and ENDURING FREEDOM.
Upon return from her second deployment, Mann reported to the United States Naval Test Pilot School, Class 135, at NAS Patuxent River, Maryland where she began her Developmental Test tour at Air Test and Evaluation Squadron TWO THREE (VX-23) as an F/A-18 Test Pilot/Project Officer. While at VX-23, Mann executed a variety of flight tests, including loads envelope expansion, flying qualities, carrier suitability and ordnance separation in the F/A-18A-F.
In the spring of 2011, Mann assumed duties as the VX-23 Operations Officer and was assigned to the PMA-281 as the Joint Mission Planning System — Expeditionary (JMPS-E) Integrated Product Team Lead just a year later. Before being selected as a NASA astronaut soon after, Mann’s military service accumulated more than 2,500 flight hours in 25 types of aircraft, 200 carrier arrestments and 47 combat missions in Iraq and Afghanistan.
Her service earned her two Air Medals, two Navy and Marine Corps Commendation Medals, two Navy and Marine Corps Achievement Medals, along with several other honors for her various academic, flight and military successes.
In 2013, Mann was selected as one of the eight members of NASA Astronaut Group 21 and completed her training two years later. She has since served as a T-38 Talon Safety and Training Officer and was the Assistant to the Chief of Exploration. She led the astronaut corps in the development of the Orion spacecraft, Space Launch System and Exploration Ground Systems. Her mission command to the International Space Station with Crew-5 was Mann’s first time traveling to space.
With Mann at mission command, Crew-5 additionally consisted of Navy Commander turned astronaut Josh Cassada, Japan Aerospace Exploration Agency astronaut Koichi Wakata and Roscosmos cosmonaut Anna Kikina. While on the space station, the team studied new biological technology advancements, such as the possibility of 3D printing human cells.
Mann is also confirmed to be a member of the Artemis program, the mission taking a group of astronauts back to the Moon for the first time since 1972. The Artemis program will launch in 2024 and cite one of the crew members as the first woman on the moon.
“It’s very exciting,” Mann told Indian Country Today upon first learning she would be the first Native American woman to officially be going to space, “I think it’s important we communicate this to our community, so that other Native kids, if they thought maybe that this was not a possibility or to realize that some of those barriers that used to be there are really starting to get broken down.”
Sources: NASA, Wikipedia, BBC, CBS, Indian Country Today
To create products that serve increasingly diverse customers and solve a wider range of social problems, technology companies need women engineers. However, only 25 percent of math and computer science jobs in the United States are filled by women, and one-third of women in the U.S. and China quit these jobs mid-career due to factors like social isolation, a lack of access to creative technical roles and difficulty advancing to leadership positions.
At Bloomberg, we’ve established a company culture that supports gender equality in a multitude of ways – from company-wide Diversity & Inclusion business plans to a newly expanded family leave policy. But we know that’s not enough. In recent years, we’ve adopted a system-wide approach to increasing the number of women in technical roles, taking steps to remove barriers to advancement both inside our organization and beyond Bloomberg, supporting female talent from middle school through mid-career.
While the number of women in technical jobs at Bloomberg is growing, we’re committed to making progress faster and completing all the steps needed to solve the equation. Here are some of the ways we’re tackling this important deficit – and making quantifiable change.
Bloomberg supports organizations that help increase women’s participation in STEM and financial technology, exposing students to various career options through Bloomberg Startup and encouraging our female engineers to engage with the next generation of talent.
Collaboration, creativity, and a love of problem-solving drew Chelsea Ohh to the field of engineering. Now she works at Bloomberg as a software engineer team lead, helping to provide critical information to financial decision makers across the globe.
Women engineers can sharpen their technical skills through open courses, on-site training sessions, and business hackathons held throughout the year. Bloomberg is committed to inspiring our female employees, eliminating barriers like impostor syndrome, and encouraging them to pursue opportunities in engineering.
Community & allies
To strengthen its network of female engineers, global BWIT (Bloomberg Women in Technology) chapters organize more than 150 events, mentoring sessions, and meet-ups a year. The community also engages male allies and advocates, sharing strategies to help them support their female colleagues.
Bloomberg Engineering’s culture champions innovation. This is made possible by the different perspectives of our 6,000+ software engineers around the globe, who come from diverse backgrounds and geographies and who possess a variety of technology specialties.
Meet four of Bloomberg’s software engineers – all of whom are active members of the Bloomberg Black in Tech Community across our New York, San Francisco and London engineering teams – and see how they’ve been empowered to impact our business globally.
Our conversations with them cover their paths to and work at Bloomberg, how they’ve grown professionally, their impact in technology, the importance of an inclusive workplace, and their efforts to attract more diversity to tech. Interviews were edited for length and clarity.
TITLE: Software Engineer BLOOMBERG OFFICE: New York
How did you get to Bloomberg? What do you work on now? I lived abroad for 5 years, during which time I taught English in South Korea for 3½ years. I then served in the U.S. Navy for 4 years, after which I felt the urge to embrace my technical talents. This career change turned out to be one of the best decisions I have ever made.
While finishing my MBA, I decided to apply to the Grace Hopper Program at Fullstack Academy, one of the country’s top-ranked coding bootcamps. This decision was the beginning of my path to Bloomberg, which I was drawn to for its philanthropic programs, the eclectic and dynamic nature of the Bloomberg Terminal, and the opportunity to be immersed in a culture of strong, talented software engineers.
I’m currently in the training program for new engineers. Prior to starting my training, I had the privilege of pre-training on the Commodities team, where I worked on building a map UI in React and Node.js and integrating it with a remote procedure call framework. I really enjoyed the learning process in discovering how to merge open source technologies with proprietary technologies.
Did you have any mentors or influential managers to guide your career along the way? One of my mentors is Erik Anderson, the software engineer who helped created MAPS<GO> and many of Bloomberg’s chart functions. Erik has helped me a great deal in building my confidence to tackle things outside my comfort zone. He really has helped me see that I was capable of more than I thought and encouraged me along the way, which really made me more driven to put in the long hours of practice and study that it takes to get to Bloomberg.
What do you love most about working in tech? I really enjoy the way it has evolved over the years and how it continues to change so rapidly. Working in technology forces me to continue learning and embrace my status as a ‘forever’ student. The moment we get too comfortable in this industry is the moment we are in danger of falling behind. There are so many advances and new technologies that, even after just one year, the older versions are quickly out-of-date. What I love most is that it is an industry that never gets too comfortable; it is about constantly improving the product and making applications faster and more efficient. The associated mental challenges and continuous learning excite me the most!
What are some of the unique challenges that people of color face getting into tech / within the tech industry? Entering a male-dominated industry doesn’t come without trepidation. Knowing that people come equipped with certain biases that they themselves may not even be aware of plays a role; it is just the way we have all been socially-programmed by the media, our parents, and our communities. The tech industry is challenging by itself and people of color may have to face a few additional challenges, dealing with variations of micro-inequities, and the burden of not contributing to certain stereotypes. However, what I enjoy the most are the raised awareness and open discussions seeking to address these imbalances. It really shows how we, as a human species, are evolving our consciousness around these issues.
In your opinion, why are diversity and inclusion important? How do you personally promote diversity and inclusion with your teams and/or in the community? Diversity and inclusion are crucial to the strength of any great organization. In order for technology to serve a wider range of users, understanding their needs and wants is very important. With the advent of globalization, this type of understanding can only be reached by increasing diversity and inclusion in the workplace.
I also enjoy sharing my experiences traveling and living abroad with my co-workers. It highlights the importance of travel as a way to break down barriers in understanding different cultures, which I believe is a pivotal step towards this objective. I am also a member of many different communities here at Bloomberg, so as not to limit the definition of myself to one particular ethnicity or background, but to expand my sense of self in order to represent the many different cultural experiences I’ve had and those I’ve adopted along the way.
TITLE: Senior Software Engineer BLOOMBERG OFFICE: New York
How did you get to Bloomberg? I was an industry hire out of a Bloomberg recruiting event in Seattle, where I met the engineers who would eventually be my managers. They were great and provided an amazing vision of the technical challenges and company culture at Bloomberg.
What do you work on now? I am presently working on designing and building out the underlying platform that supports Bloomberg’s Asset Investment Management (AIM) compliance workflows.
Did you have any mentors to guide your career along the way? Most definitely! I was fortunate to have an awesome mentor when I first started at Bloomberg. He was one of those engineers whose code nuances and expressiveness are like revelations. I learned a lot about my team and Bloomberg’s culture just by contributing to his code. I was also fortunate to have supportive managers who accommodated my desire to be challenged. They were able to provide interesting, tangible and business-critical projects to broaden my scope and contributions.
What do you love most about working in tech? It has been said that engineers are the gatekeepers for civilization. Being in tech is like a calling. The work one does has a direct impact on the well-being of others. It gets more interesting when your work pushes the boundaries of what is considered possible. When this happens, there is no greater feeling than creating something new. Then you realize that, in some small way, you’ve (hopefully) helped make the world just a bit better than before.
Are there any particular technologies that interest you? Machine learning, especially around the areas of natural language processing and understanding. The best technologies are those that feel so completely natural and intuitive that you may forget that you are interacting with a machine. Ironically, it is extremely difficult to create such a system. Applications of ML have the powerful potential to change the way we all interact with technology, if not the very nature of the machines we use.
What are some of the unique challenges that people of color face getting into tech / within the tech industry? There are very few of us in the tech industry. This truism begs us to ask why, as demographics don’t support this reality, as 10% of all college graduates and computer science majors are people of color. It’s sometimes hard not to feel excluded when there are very few people who look like you in the places that you are or want to be. There is often a significant effort required to go from ‘person of color,’ to ‘person,’ to ‘extremely capable person’ in the minds of others that people of other backgrounds do not face.
In your opinion, why are diversity and inclusion important? Antifragility is a term coined by bestselling author Nassim Nicholas Taleb that describes systems that thrive in the face of volatility, shock or adversity. It represents the next step beyond robustness and resilience. I believe that, by their very nature, antifragile systems are diverse. Events that could take down a monoculture are often integrated and used for the greater good by an antifragile system. Diversity and inclusion promote antifragility by fostering teams that are tolerant, supportive, engaging and dynamic.
How do you personally promote diversity and inclusion with your teams and/or in the community? I am one of the co-founders of the Bloomberg Black In Tech (BBIT) Community, which is composed of individuals in technology roles across Bloomberg – in engineering, product management, data science, etc. BBIT’s singular goal is to make Bloomberg the best place for minorities in tech across the industry. We host regular events to foster professional and personal development and create a fun, safe space. We work very hard to engage, support and empower the community at large through mentoring, recruiting, and outreach events on college campuses and at tech conferences with significant minority representation.
TITLE: BQuant Specialist, Desktop Build Group BLOOMBERG OFFICE: San Francisco
How did you get to Bloomberg? What do you work on now? I spent the first five years of my career at leading French banks where, among other things, I designed and implemented technology to automate processes on trading floors. Bloomberg found me on LinkedIn and recruited me to our London office in 2013. I’ve now worked in our San Francisco office for five years.
I’m currently a BQuant Specialist in our Desktop Build Group. In this role, I educate our clients’ quantitative financial researchers, analysts, and data scientists to leverage BQuant, our interactive data analysis and quantitative research platform and new Bloomberg Query Language (BQL). To do this, I first have to understand our clients’ workflows and determine how and where our quant research solutions can help them derive value. Often, we can help clients reduce the amount of time and manual labor spent reviewing financial statements. We can incorporate probability and statistics that help clients make faster and more accurate decisions on their financial strategies. Many times, I create the specifications, design a custom application for a team of about 20-50 users, test the app, and implement it at the client site. Finally, I help train users to program in Python in order to leverage BQuant.
Did you have any mentors or influential managers to guide your career along the way? It has been challenging finding a Black professional mentor. David Mitchell, a team leader for our market specialists, has been a huge inspiration for me. We both started our careers in finance and moved to tech, so I feel like we have much in common. I appreciate how he reaches out periodically to check in on me. I admire his leadership of Bloomberg’s Black Professional Community and am really impressed by his career trajectory and the network he has built. It’s really important to see a person of color in a senior position because it makes that rank seem attainable for the rest of us.
Sandra Lee, who works in Bloomberg’s Product Oversight Office, has also been an influential mentor since we first met in 2016. She’s been with Bloomberg for more than 20 years, and she has helped me understand Bloomberg’s culture and navigate internal networks. I often use her as a sounding board to help me articulate my vision and get a second opinion. On a personal level, she shows me the value of work-life balance.
What do you love most about working in tech? I love being in a position where I’m learning something. Technology is perpetually evolving, and you always need to be on your toes to remain competitive. I will often think about a complex engineering challenge that I am trying to solve, and will have a candid conversation with a colleague or I will read an article, and then a solution will emerge. I then implement it and it is so satisfying when it works. I also like that tech has tangible results.
Are there any particular technologies that interest you? I am really excited about artificial intelligence (AI) and machine learning (ML). I love the idea that technology can show us patterns that humans cannot otherwise see because we cannot scrape through large volumes of data as quickly. From there, we can extract specific insights that influence our decision-making.
My interest in AI and ML led me to complete a graduate-level certificate program at the University of San Francisco. While I’m not using these skills in my current role, I’m excited that Bloomberg is doing cutting-edge work in natural language processing and other areas related to ML and AI. I’ve also joined Bloomberg’s Machine Learning Guild so I can stay connected to this technology; otherwise, it is hard to stay on top of it when you don’t apply it on a daily basis.
What are some of the unique challenges that people of color face getting into tech / within the tech industry? One word: R-E-P-R-E-S-E-N-T-A-T-I-O-N! We need to see peers and leaders who are people of color. When I don’t see people of color in leadership positions, I feel like it’s less possible to attain success. When I see Black leaders, I get a lot of motivation and affirmation that it could be me one day.
In my experience, people of color aren’t taken as seriously by their peers unless there are other people of color in leadership positions. I personally feel like I need to be better than anyone else in whatever I’m doing. I don’t want to give any opening for the quality of my work to be questioned. For that reason, I often spend extra time double-checking my work in order to make everything is perfect. No one asks me to do this, but I feel I must. This adds a dimension of extra stress because that workflow is not scalable or sustainable and can lead to burnout.
In your opinion, why are diversity and inclusion important? How do you personally promote diversity and inclusion with your teams and/or in the community? Life is so much more fulfilling when you can interact with people from different backgrounds and ways of life. At work, a diverse team can help prevent tunnel vision when solving challenges or meeting client needs. Everyone comes with baggage and biases that sometimes makes communication uncomfortable, but this ultimately leads to rich learning experiences.
I’m always trying to recruit and advocate for more underrepresented minority candidates, because we are only likely to stay at Bloomberg if we continue seeing more diversity on our teams.
Jonathan “JC” Charlery
TITLE: Senior Software Engineer BLOOMBERG OFFICE: London
How did you get to Bloomberg? I was on my way to interview with a different company during the career fair at Howard University, when I ran into Kerry Joseph, an engineer who was recruiting for Bloomberg. We got to chatting about the company and he invited me to an info session later that night. What struck me was how down-to-earth and genuine he was. He wasn’t trying to sell me anything; he just talked about his own experiences at the company and how the job allowed him to grow.
In talking about his own background, we discovered we were from neighbouring islands in the Caribbean so we shared a cultural background. Having that conversation, and seeing and hearing someone like me at Bloomberg who had such a positive experience is what really sold me on the company.
What do you work on now? I’m on the Local Development team in London, which is part of our Developer Experience (DevX) group. Our team creates and supports the tools and workflows that allow engineers to develop and test their applications locally on their laptops using whatever tools they prefer, instead of relying on a limited shared environment.
Did you have any mentors or influential managers to guide your career along the way? Zac Rider, who leads our Real-time Distribution Platform engineering team, and Becky Plummer, a software engineering team leader in DevX (and my current manager) are two of the most influential managers I’ve had during my tenure at Bloomberg. They’ve provided me with many opportunities for growth and helped me build up my confidence in my own abilities. They were instrumental in putting my career on its current trajectory.
Femi Popoola, a technical team lead in London, has also been an amazing mentor to me. We’ve spoken about many different topics related to personal and technical growth, like knowing which opportunities are right for you and how to manage them, to understanding when you’re ready to take on a new challenge (hint: you’re never going to be “ready,” but don’t let that stop you).
What do you love most about working in tech? I love the rate at which everything changes in the tech industry, and the ease of being able to get involved.
The tech industry evolves so quickly that you’ll miss it if you blink. In the last 20 years or so, we’ve gone from having one dedicated phone line per family and maybe having a computer for the household to us all having a computer in our pockets and everyone having a phone. All the information this puts at our fingertips has made it much easier for anyone to become involved and even to transfer into tech-related fields from any profession.
Are there any particular technologies that interest you? Docker and container technologies are particularly interesting to me. The ability to simulate an entire environment and have repeatable declarative processes have really changed the way we think about development, testing, and stability of our systems.
What are some of the unique challenges that people of color face getting into tech / within the tech industry? Without seeing other people who look like them or can stand as a role model for them, people of colour tend to get discouraged from entering the tech industry. It is hard to continue being self-motivated or to believe you can achieve something if all the stereotypical icons don’t represent you in any way. It’s why Kerry stood out to me so much. He was West Indian and able to succeed in the tech industry. This isn’t spoken about often, but it creates a real psychological barrier for many people. Being able to connect with someone who shares your heritage or cultural background, and being able to see yourself in that person, are some of the greatest motivating factors.
In your opinion, why are diversity and inclusion important? Diversity and inclusion are very important as they provide different perspectives. Having someone who can see something in a different manner and who brings their own background and experiences can help elicit a new style of thinking and new direction when it is needed the most. When all options have seemingly been exhausted, something which may seem intrinsically basic to someone can actually be just what is needed to get things moving again.
How do you personally promote diversity and inclusion with your teams and/or in the community? I’ve spoken at events aimed at promoting and highlighting diversity and inclusion, as well as been a representative, speaker and mentor at both internal and external events aimed at empowering underprivileged youth to encourage them to pursue careers in STEM and grow their networks. This includes serving as a mentor to both university students and secondary school students.
I have been an advocate for and given advice about different ways to recruit effectively at select Historically Black Colleges & Universities (HBCUs) across the U.S. I’ve also attended university career fairs where I directly engage with students, serving not only as a company point of contact for them, but also sharing my experiences with them. I talk to new hires about my career progression and serve as a mentor to help them navigate the company’s culture.
Have you ever wondered what the outlook might be for your STEM career five or even ten years out? Or maybe you are a current student weighing your options for a chosen career path and need to know the type of degree that is required.
Oak Ridge Institute for Science and Education labor trends and workforce studies experts have culled through the BLS data and have summarized the outlook for several select STEM careers.
With the right information in-hand — and a prestigious research experience to complement your education — you can increase the confidence you have when selecting a STEM career.
There are over 1,469,000 software developers in the U.S. workforce either employed as systems software developers or employed as applications software developers. Together, employment for software developers is projected to grow 22 percent from 2019 to 2029, much faster than the average for all occupations.
Software developers will be needed to respond to an increased demand for computer software because of an increase in the number of products that use software. The need for new applications on smart phones and tablets will also increase the demand for software developers. Software developers are the creative minds behind computer programs. Some develop the applications that allow people to do specific tasks on a computer or another device. Others develop the underlying systems that run the devices or that control networks. Most jobs in this field require a degree in computer science, software engineering, or a related field and strong computer programming skills.
Software developers are in charge of the entire development process for a software program from identifying the core functionality that users need from software programs to determining requirements that are unrelated to the functions of the software, such as the level of security and performance. Software developers design each piece of an application or system and plan how the pieces will work together. This often requires collaboration with other computer specialists to create optimum software.
Atmospheric sciences include fields such as climatology, climate science, cloud physics, aeronomy, dynamic meteorology, atmosphere chemistry, atmosphere physics, broadcast meteorology and weather forecasting.
Most jobs in the atmospheric sciences require at least a bachelor’s degree in atmospheric science or a related field that studies the interaction of the atmosphere with other scientific realms such as physics, chemistry or geology. Additionally, courses in remote sensing by radar and satellite are useful when pursuing this career path.
According to the Bureau of Labor Statistics (BLS), computer models have greatly improved the accuracy of forecasts and resulted in highly customized forecasts for specific purposes. The need for atmospheric scientists working in private industry is predicted to increase as businesses demand more specialized weather information for time-sensitive delivery logistics and ascertaining the impact of severe weather patterns on industrial operations. The demand for atmospheric scientists working for the federal government will be subject to future federal budget constraints. The BLS projects employment of atmospheric scientists to grow by 8 percent over the 2018 to 2028 period. The largest employers of atmospheric scientists and meteorologists are the federal government, research and development organizations in the physical, engineering, and life sciences, state colleges and universities and television broadcasting services.
Electrical and Electronics Engineers
According to the Bureau of Labor Statistics (BLS), there are approximately 324,600 electrical and electronics engineers in the U.S. workforce. Workers in this large engineering occupation can be grouped into two large components — electrical engineers and electronics engineers. About 188,300 electrical engineers design, develop, test or supervise the manufacturing of electrical equipment, such as power generation equipment, electrical motors, radar and navigation systems, communications, systems and the electrical systems of aircraft and automobiles. They also design new ways to use electricity to develop or improve products. Approximately 136,300 electronics engineers design and develop electronic equipment such as broadcast and communications equipment, portable music players, and Global Positioning System devices, as well as working in areas closely related to computer hardware. Engineers whose work is devoted exclusively to computer hardware are considered computer hardware engineers. Electrical and electronics engineers must have a bachelor’s degree, and internships and co-op experiences are a plus.
The number of jobs for electrical engineers is projected by BLS to grow slightly faster (9 percent) than the average for all engineering occupations in general (8 percent) and faster than for electronics engineers (4 percent) as well. However, since electrical and electronics engineering is a larger STEM occupation, growth in employment is projected to result in over 21,000 new jobs over the 2016-2026 period. The largest employers of electrical engineers are engineering services firms; telecommunications firms; the federal government; electric power generation, transmission and distribution organizations such as public and private utilities; semiconductor and other electronic component manufacturers; organizations specializing in research and development (R&D) in the physical, engineering and life sciences; and navigational, measuring, electro-medical and control systems manufacturers.
BLS notes three major factors influencing the demand for electrical and electronic engineers. One, the need for technological innovation will increase the number of jobs in R&D, where their engineering expertise will be needed to design power distribution systems related to new technologies. They will also play important roles in developing solar arrays, semiconductors and communications technologies, such as 5G. Two, the need to upgrade the nation’s power grids and transmission components will drive the demand for electrical engineers. Finally, a third driver of demand for electrical and electronic engineers is the design and development of ways to automate production processes, such as Supervisory Control and Data Acquisition (SCADA) systems and Distributed Control Systems (DCS).
Data Science and Data Analysts
Technological advances have made it faster and easier for organizations to acquire data. Coupled with improvements in analytical software, companies are requiring data in more ways and higher quantities than ever before, and this creates many important questions for them, including “Who do we hire to work with this data”? The answer is likely a Data Scientist.
When trying to answer the question “what is data science,” Investopedia defines it as providing “meaningful information based on large amounts of complex data or big data. Data science, or data-driven science, combines different fields of work in statistics and computation to interpret data for decision-making purposes.” This includes data engineers, operations research analysts, statisticians, data analysts and mathematicians.
The BLS projects the employment of statisticians and mathematicians to grow 30 percent from 2018-2028, which is much faster than the average for all occupations. According to the source, organizations will increasingly need statisticians to organize and analyze data in order to help improve business processes, design and develop new products and advertise products to potential customers. In addition, the large increase in available data from global internet use has created new areas for analysis such as examining internet search information and tracking the use of social media and smartphones. In the medical and pharmaceutical industries, biostatisticians will be needed to conduct the research and clinical trials necessary for companies to obtain approval for their products from the Food and Drug Administration.
Along with that of statistician, the employment of operations research analysts is projected by the BLS to grow by 26 percent from 2018-2028, again much faster than the average for all occupations. As organizations across all economic sectors look for efficiency and cost savings, they seek out operations research analysts to help them analyze and evaluate their current business practices, supply chains and marketing strategies in order to improve their ability to make wise decisions moving forward. Operations research analysts are also frequently employed by the U.S. Armed Forces and other governmental groups for similar purposes.
To learn more about other flourishing careers in STEM, visit bls.gov/ooh to learn more.
The cows in Farmer John’s pasture lead an idyllic life. They roam through tree-shaded meadows, tearing up mouthfuls of clover while nursing their calves in tranquility.
Tawny brown, compact and muscular, they are Limousins, a breed known for the quality of its meat and much sought-after by the high-end restaurants and butchers in the nearby food mecca of Maastricht, in the southernmost province of the Netherlands. In a year or two, meat from these dozen cows could end up on the plates of Maastricht’s better-known restaurants, but the cows themselves are not headed for the slaughterhouse. Instead, every few months, a veterinarian equipped with little more than a topical anesthetic and a scalpel will remove a peppercorn-size sample of muscle from their flanks, stitch up the tiny incision and send the cows back to their pasture.
The biopsies, meanwhile, will be dropped off at a lab in a nondescript warehouse in Maastricht’s industrial quarter, five miles away, where, when I visit in July, cellular biologist Johanna Melke is already working on samples sent in a few days prior. She swirls a flask full of a clear liquid flecked with white filaments—stem cells isolated from the biopsy and fed on a nutrient-dense growth medium. In a few days, the filaments will thicken into tubes that look something like short strands of spaghetti. “This is fat,” says Melke proudly. “Fat is really important. Without fat, meat doesn’t taste as good.”
On the opposite side of the building, other scientists are replicating the process with muscle cells. Like the fat filaments, the lean muscle cells will be transferred to large bioreactors—temperature- and pressure-controlled steel vessels—where, bathed in a nutrient broth optimized for cell multiplication, they will continue to grow. Once they finish the proliferation stage, the fat and the muscle tissue will be sieved out of their separate vats and reunited into a product resembling ground hamburger meat, with the exact same genetic code as the cows in Farmer John’s pasture. (The farmer has asked to go by his first name only, in order to protect his cows, and his farm, from too much media attention.)
That final product, identical to the ground beef you are used to buying in the grocery store in every way but for the fact that it was grown in a reactor instead of coming from a butchered cow, is the result of years of research, and could help solve one of the biggest conundrums of our era: how to feed a growing global population without increasing the greenhouse-gas emissions that are heating our planet past the point of sustainability. “What we do to cows, it’s terrible,” says Melke, shaking her head. “What cows do to the planet when we farm them for meat? It’s even worse. But people want to eat meat. This is how we solve the problem.”
When it comes to the importance of fat in the final product, Melke admits to a slight bias. She is a senior scientist on the Fat Team, a small group of specialists within the larger scientific ecosystem of Mosa Meat, the Maastricht-based startup whose founders introduced the first hamburger grown from stem cells to the world eight years ago. That burger cost $330,000 to produce, and now Melke’s Fat Team is working with the Muscle Team, the (stem cell) Isolation Team and the Scale Team, among others, to bring what they call cell-cultivated meat to market at an affordable price.
They are not the only ones. More than 70 other startups around the world are courting investors in a race to deliver lab-grown versions of beef, chicken, pork, duck, tuna, foie gras, shrimp, kangaroo and even mouse (for cat treats) to market. Competition is fierce, and few companies have allowed journalists in for fear of risks to intellectual property. Mosa Meat granted TIME exclusive access to its labs and scientists so the process can be better understood by the general public.