Tag: #semiconductors

Solving Power Management Problems with Emerging Technologies

September 4, 2018 / Hannah / 0 Comments

On Episode 73 of The Edge of Innovation, we’re talking with entrepreneur Simon Wainwright, president of Freebird Semiconductor, about solving power management problems with emerging technologies.

Show Notes

Freebird Semiconductor’s Website
Contact Freebird Semiconductor
Find Simon Wainwright on LinkedIn
What is GaN?
Freebird Semiconductor to attend and present at 2018 Space Parts Working Group
Incredible Hulking Facts about Gamma Rays
Displacement Damage Testing
The Radiation Laboratory at UMass Lowell
Texas A&M University – The Cyclotron Institute
Die Adaptor (FDA) Products from Freebird Semiconductor
What Is Hermeticity?
Link to SaviorLabs Assessment

Sections

Three Types of Radiation Testing
Device Performance Based on Testing
The Entrepreneurial Rollercoaster Day
How Freebird Semiconductor Got It’s Name
What Do We Do?
Should You Start Your Own Business? Advice From Simon
The Three Freebird Semiconductor Products
What is Hermetically Sealed?

Solving Power Management Problems with Emerging Technologies

Three Types of Radiation Testing

Paul: Alright, so you do radiation testing too. Now that sounds exciting/scary. How do you do that?

Simon: There are essentially three basic different types of radiation. So I’ll run you through each of those three. So the first one is gamma radiation. It sounds like something out of a comic book, doesn’t it?

Paul: Yeah. Exactly. Well, I think there was the Hulk, right?

Simon: That’s right. That’s what I was talking about. All the components turn green and break out of their packages.

Paul: So yeah. If I see some of your employees running from the building like that, we’ll know. Okay.

Simon: That’s when we ask them to do the radiation testing. So the basic gamma, you have a radioactive source, which essentially looks like a pencil shrouded by lead. And then you lift the lead up, and it emits radiation, and you put your parts in the path of that radiation, and you can measure the dose that it receives. And that’s called total ionizing dose. Gamma radiation, that’s one of the three types.

And you can do high-dose rates. So you can do a very quick rate of exposure, or you can do a slower dose rate. We don’t see any difference. So we do the high dose rate so we can test things faster.

Then we have displacement damage, which is essentially neutrons. So you bombard these with a flow of neutrons and that essentially is like trying to see whether the neutrons actually displace the lattice, the crystal lattice of the things causing electrical defects and therefore non-functionality of the part. We actually do both of those things locally. The neutron, the displacement damage in the University of Lowell and the gamma radiation in a local company out in Chelmsford.

Paul: Oh, cool.

Simon: And then the third one is ion. Ion bombardment essentially. So it’s called single event effect. So there are different types of single-event effects. We go down to Texas A&M, so Texas. I think it’s agricultural and mechanical university down in…

Paul: I, I think it’s agriculture and mining actually. But yeah…

Simon: I just see the bills.

Paul: I know. I understand.

Simon: So we, we go down to TAMU and we use their cyclotron. So they have this almost like a big washing machine full of lots of different ions and atoms. They accelerate them around in a circle, and then basically, they open a door and certain ions of a specific weight leave. So you can, by opening the door at different energy levels, so to speak, you can tune it in so that different ion species come out. So we test with two different ions species — xenon and gold. So we fire gold at our devices while they’re biased, and that’s the same as if you get a… You imagine a swimming pool full of ping-pong balls, you get a bowling ball, and you throw it in, that’s what we’re trying to simulate to see how that affects the structure.

Paul: And so you’re doing these because I would imagine there’s some mapping to real world events.

Simon: It’s the closest we can get on Earth to maybe an ion that’s floating around in space from a solar flare, for instance, so you get stray ions that are just floating around, and you may get hit by an ion, an ion atom, or ion, at least.

Paul: An ion. Yeah, exactly. So that’s how it maps back. So there are these things in space that are just moving around and you need to be, if you’re in the way, you need to be hardened to that. Or certainly understand the failure mode before you send it there.

Simon: Exactly.

Paul: Wow. Who’d a thunk?

Simon: Yeah. Exactly. So we’ve had great success with that in fact. So we’re very proud of our results for that in our product portfolio.

Device Performance Based on Testing

Paul: And is one device compared to the next device going to have different performance based on that and what is the different? If it is different, what would make it different?

Simon: I would say, if you buy a commercially available device of anything, yes, that is the case. But if you buy a specifically radiation-hardened parts, then no. We have to eliminate that variability upfront. Otherwise, we don’t have a business. We’re playing roulette. Do we get good lots?

Paul: But is it intrinsically because of the way you built it? Is it the materials you used? What makes the cake taste good each time? Is it because you’ve used good flour, good sugar, you know, all the precise recipe, or is it something else?

Simon: No, we keep a very tight control. Firstly, there is a difference in the process, which I won’t go into the details, but there is a difference in the process that allows us to have this performance, which we worked very closely with EPC to develop. Then secondly, we do a lot, as I said, of screening, a lot of testing. So we have a very, very tightly controlled process. And then, not only do we have a tightly controlled process for the chips that come off the line, we then verify that with all these screenings and conformance inspections and life tests before we actually ship.

Paul: So are you going to be like Intel where you take the chips that are partially failed and just make it an i3 and an i5 and different clock frequencies?

Simon: I’m saying nothing about Intel. I don’t want a lawsuit from Intel.

Paul: Well, but so, I mean, is there a market for your underperforming parts?

Simon: Yeah. We convert them into commercial parts. Electrically, they will be within spec or they won’t even get that far. So then people can use them for doing their tests, their engineering tests on a breadboard or something like that. So that can use that, and they don’t have to go through all of the radiation testing. Electrically, they will be the same. It’s just that they would not be as rugged, radiation-wise.

The Entrepreneurial Rollercoaster Day

Paul: So let’s get back to the entrepreneurial idea, the business idea. It’s, again, when you wake up Monday morning, you’re not employed. You gotta get up and do the work. Have there been any anecdotes you can think of that are like, “Oh, my gosh. What have I gotten myself into?” Or…

Simon: Every day is a rollercoaster. Every high is very high. Every low is very low because you know that nobody else is going to step in and, and solve it for you. And that’s the same, I imagine, in any business. And, there’s nowhere to hide.

Paul: That’s true.

Simon: There’s nowhere to hide. You are it. You are it. You know, the buck stops with you, and that’s the biggest, you know. If you work for somebody else, you can go out. You go to work. You come home, and you can forget about it until the following day. We, we can’t turn off. We can’t turn off.

Paul: That’s true, but it is fun.

Simon: Oh, absolutely.

Paul: It is very much fun.

Simon: You know, it gives you a certain flexibility in life as well, I would say, as well.

Paul: You know, what I find is it’s the creativity that you’re allowed to do that getting things to work. It, it’s complicated. It’s hard getting people to do what they’re supposed to do, I can imagine. So you’ve got not only the people part, but you’ve got the technology part. We’re in a world where we do some creative work, but we make technology work. So we’re not like inventing the computers. We’re just making them work, and you’re inventing the computer as well as making it work. And you’ve got to manage the people doing it.

Simon: At least the power supply.

How Freebird Semiconductor Got It’s Name

Paul: A least the power supply. Yeah, exactly. Very cool. So we’ve been talking with Simon Wainwright, president of Freebird Semiconductor. What’s with the name?

Simon: Oh, there are three different reasons, and depending on who you are, I give a different reason. So I’ll go through each of them. Please, nobody who is listening to this tell anybody else. This is secret. So firstly, the three owners, the three founders worked at the same company, and we left the company, so we were free birds. So we spread our wings and we left. That, that’s one.

Paul: That’s one story. That’s a good story. Okay.

Simon: That’s one of the versions. The second version is that a bird is a colloquialism in the space industry for a satellite. So it’s a free bird.

Paul: They’re certain not free, though.

Simon: Ask the accountant about that. So yeah. So it’s a bird. It’s a colloquialism for a satellite, is a bird.

And then the third one is that, you must have heard of Lynyrd Skynyrd, so there you go.

Paul: Well, what about Lynyrd Skynyrd?

Simon: We’re all from that era. We were in a bar in California, and, “What should we call the company?”

Paul: Did the song come on?

Simon: What came on the jukebox?

Paul: Did it really?

Simon: Freebird.

Paul: Are you serious?

Simon: Absolutely, yeah.

Paul: Oh, that’s cool.

Simon: But you’d be surprised how effective the name is because a lot of people associate it with the song and they say, “Ah…” And of course, we’re cool guys, so when we talk to procurement guys or whatever, they all remember that.

Paul: That’s cool.

Simon: But all three of the reasons I gave you really contributed to the name, I’d say.

Paul: I would have never imagined you could have gotten even the domain name nowadays. You know there are so many that are taken. That’s great!

Simon: Nobody want to be a freebird semi.

Paul: Semi freebird. Fascinating.

What Do We Do?

Paul: So yes, we’re sitting here with Simon Wainwright, president of Freebird Semiconductor. What would you say, if you were talking to the technical person? Say, “Hi, I’m Simon from Freebird Semi. We do…” You said GaN?

Simon: We solve power management problems with emerging technologies such as gallium nitride.

Paul: Wow. So that’s your elevator pitch.

Simon: That is what we do.

Paul: That’s what we do?

Simon: That’s what we do.

Paul: And is that what you tell nontechnical people?

Simon: I tell them that we’re faster, smaller, better, and we’re even nice guys.

Paul: We’re even nice guys. Okay.

Should You Start Your Own Business? Advice From Simon

So is there anything you’d like to cover, some specific things we haven’t talked about that you’d be interested…?

Simon: About business?

Paul: Yeah, business or…

Simon: No, I think it’s just a great way of making a living. We’re having fun. If there are people out there debating whether to become entrepreneurs or not, then do it, is the answer. But beware. You’re know, you’re going to have stressful nights. You know, it’s going to be tough. It’s not easy.

Paul: Have you had any good mentors, people that you’ve gone to when you’ve been like, “What do I do in this situation?” Or have you been pretty much organic?

Simon: No, we’ve been pretty much organic. The three of us are really tight. You know we shout at each other, but we hug each other as well, you know. So it’s good to have that backup of your other two partners, whichever of the three you are, you always have the backup of the other two partners.

Paul: That’s a good point. So would you recommend that over going it alone?

Simon: I’m not sure to be honest. I’ve done both. They’re both equally as good.

Paul: Or as difficult.

Simon: Yeah.

Paul: It’s not like it solves all your problems, having two other partners.

Simon: No. It doesn’t solve all your problems. Sometimes it creates them. You know, the thirds the thirds the worry.

The Three Freebird Semiconductor Products

Paul: So, how many parts do you have, model parts do you have? Or what’s your portfolio?

Simon: So our portfolio, we have three main products. Well, no, three main product ranges, ranges. So we have hermetically-sealed parts.

What is Hermetically Sealed?

Paul: In a Funk & Wagnalls doorstep with… So hermetically sealed. What is hermetically sealed? Everybody has heard that. Who is Hermie? Hermetic?

Simon: So he’s a guy that lives down the street.

Paul: Yeah. And he seals them for you.

Simon: That’s right. So we basically have a box. It’s essentially like a box that we connect the chip inside. There are connections that come out through that box, and then we put a lid on the box, and nothing can get in or out of that. So we try and fill the box up with nitrogen. Then we close the box, and basically, that is to protect the parts from moisture when they’re on the ground. There’s no weather in space. Space is a vacuum, so there’s no problem in space. But it’s to protect the parts. If they go down o Florida and sit on a launch pad for a couple of weeks in the humidity, it’s to stop moisture getting in and affect the electrical parameters of the part. So that’s the first, the hermetically-sealed parts, which we call the FBG series.

Then we have an even smaller version of that, which is called the FDA series, the Freebird Die Adapter series. So these are on a ceramic header, but there is no box. So this is a smaller version, almost a chip-scale product.

Paul: So how big is this physically? Quarter of an inch, eighth of an inch?

Simon: I can give it to you in mils.

Paul: Oh, okay. A scientist!

Simon: So the hermetically packaged part would be, a typical part would be 220 mils. So 0.22 inches by 0.15 inches. And that can conduct 30 amps. Yeah.

Paul: And not just like for a half a second.

Simon: No, no. Like, constantly.

Paul: Constantly. Wow. How do you get the conductors to get to that?

Simon: Big wires.

Paul: I guess. I mean, coming down to this little tiny thing.

Simon: No, I mean, it’s everything is designed correctly to match that. But that’s 0.22 by 0.15 of an inch would be a 30-amp device. And we can go smaller, and we can go slightly larger but that’s a 30-amp devices there. If we take that same chip onto the FDA series, which is the chip level part, then we are looking at… Now I only know this one in millimeters. So you’re going to have to do some… You don’t get a free ride here.

Paul: 25.4 millimeters per inch. Okay. Go ahead.

Simon: You’re going to have to do some math on this. So, it’s roughly 4 millimeters by 1.5 millimeters.

Paul: So a little bit smaller.

Simon: So what’s that? Yeah.

Paul: 4/25 of an inch would be 2/13… 1/6 of an inch.

Simon: It’s about a third of the actual area of the hermetically…

Paul: Wow. And the same 30 amps?

Simon: Mm-hmm. The same. The same chip. The same chip.

Paul: Interesting.

Simon: Not in a box. It’s set on a platform.

Paul: Okay. So really, the differences between your products are the packaging.

Simon: Yeah. We, we have a range of products that goes from 40 volts through 100 volts to 200 volts, and then we have, uh, a standalone product which is 300 volts—

Paul: I see. Oh, cool.

Simon: —in terms of capability. Then the third product range that we have is a module. So we actually design circuits with our chips, with, the chip scale parts. We create a functional building blocks for power supplies. And for the more technical listener, it’s a half-bridge circuit with a driver. So we’re actually the first company in the world to actually supply gallium nitride drivers to drive the gallium nitride switch, which is the 30-amp on the output.

Paul: Very cool. So and you’re building these. Are these all built in Haverhill?

Simon: Yeah, yeah.

Paul: Wow. Who would’ve thunk it. I mean, in Haverhill, Massachusetts we’re doing such cutting edge technology. That’s really great.

Simon: Yeah, it’s good. We’re involved with a lot of very important companies and institutions as well.

Paul: Excellent. Well, you’ll have all the contact information for Simon and his team in our show notes, his website. And if we could get some maybe pictures of some of the technology that would be interesting for the listeners to see. That would be really cool because I think it would be neat, if you’re interested in this, or if you know somebody who is interested in this kind of technology, just to look at that and see what it’s doing and what it replaces. So we can have that as well. But anyway, well, thank you very much for your time and we really appreciate you coming in and hope to talk to you next time.

Simon: No problem.

Paul: Alright.

Simon: Thank you very much.

More Episodes:

You’ve been listening to Part 3 of our interview with Simon Wainwright! If you missed Part 1, you can listen to it here and if you missed part 2, you can find it here!

Also published on Medium.

The Future of the Space Industry: Gallium Nitride Semiconductors

August 21, 2018 / Hannah / 0 Comments

On Episode 72 of The Edge of Innovation, we’re talking with entrepreneur Simon Wainwright, president of Freebird Semiconductor, about Gallium Nitride technology and the future of the space industry.

Semiconductor Manufacturing With Entrepreneur Simon Wainwright

August 7, 2018 / Hannah / 0 Comments

On Episode 71 of The Edge of Innovation, we’re talking with entrepreneur Simon Wainwright, president of Freebird Semiconductor, about how he started a company to manufacture semiconductors using GaN technology!

Show Notes

Freebird Semiconductor’s Website
Contact Freebird Semiconductor
Find Simon Wainwright on LinkedIn
Space X – A private company that manufactures and launches advanced rockets and spacecraft
What’s So Special About Low Earth Orbit?
OneWeb: Bringing global, satellite-based internet services to Earth through a constellation of satellites
Project Loon: Balloon Powered Internet For Everyone
What is a Transistor?
What is GaN?
Link to SaviorLabs Assessment

Sections

Introduction
Starting a Semiconductor Manufacturing Company
About Simon Wainwright
A Team of Entrepreneurs
Starting a Company From Ground Zero
The Risks – Believing in Your Company From Day One
The Execution of a Business Idea
What on Earth is Going on In Space Right Now?
The Market for Satellites and Small Constellations
What Are Constellations Doing Right Now?
What is a Semiconductor?
The Market for Semiconductors
Wireless Charging With Gallium Nitride Technology
More Episodes

Semiconductor Manufacturing with Simon Wainwright

Introduction

Paul: Hello. Today I’m here with Simon Wainwright. President of Freebird Semiconductor out of Haverhill, Massachusetts.

Simon: Hi. Good afternoon, Paul. How are you?

Paul: Welcome. Thank you for coming in.

Simon: No problem.

Paul: So we met probably two years ago now?

Simon: Yeah, I’d say so. Yeah.

Paul: And you were starting a new semiconductor company.

Simon: That’s correct. Yeah.

Starting a Semiconductor Manufacturing Company

Paul: You know, our audience is quite diverse. You’ve got just normal people that have no idea what a semiconductor is to really technical people that can probably build semiconductors. Some of your competitors are people that we work in the same realm in manufacturing world. Why did you start a semiconductor manufacturing company? And how long has it been? Two years, three years now?

Simon: Yes, it’s been alive now for about two years, eight months. Something like that.

Paul: So what was the inflection point? What caused you to say, “Yeah, I’m going to start a semiconductor manufacturing company”?

Simon: It was the advantages of the technology. We work with gallium nitride, which is an emerging technology. It’s been around in the research realms for about ten, fifteen years. And then maybe in mainstream RF, or radio frequency type circuits for a little bit longer than it has been into the main power markets. But we had a relationship with the CEO and founder of another company called Efficient Power Conversion who is actually our foundry supplier of gallium nitride. And the technology just has advantages that make it… It really is an offer we couldn’t turn down. We can make things smaller, faster, more efficient and cheaper.

About Simon Wainwright

Paul: Okay. Well let’s get into that a little bit. So first of all, before we do that, what’s your background? I can tell you’re not from Boston.

Simon: I’m from Old England.

Paul: Old England. That’s right. Not New England. Okay. That’s a good point.

Simon: That’s right. So I’m from the UK. I studied electrical engineering, electronic engineering, at the University of Liverpool. I followed that through with a PhD in silicon uninsulated technology, believe it or not, which is now mainstream. Then I moved to Spain, my personal life took me to Spain for 20 years where I was a partner in one of the semiconductor companies in Spain as well.

Paul: So this is right in your wheelhouse.

Simon: Absolutely. Yeah.

Paul: So it wasn’t like you were a baker and you say, I’m going to wake up and I’m going to make semiconductors today.

Simon: Oh, no, no, no. I’ve always been involved in semiconductors in one form or another.

Paul: Okay. And what brought you to New England?

Simon: Basically, in my Spanish company, I was trying to sell to an American company, and they said, “Hey, we don’t want to buy your chips, but we want to hire you.” So I got a job with this company, and they ultimately brought me over about six years ago now.

Paul: So you’re relatively new to the United States.

Simon: Yeah, I’m very new.

Paul: Alright. Have you always been in New England, or did you live somewhere else?

Simon: Always here. Strangely enough, the Spanish company had an office in Andover, which is just down the road from Haverhill where we are located now. So I’ve had an association with the area for 25 years.

A Team of Entrepreneurs

Paul: Okay. Cool. So you didn’t just sort of sit up one day and say, “Hey I’m going to do this.” You didn’t do it alone. You have a key team, I would imagine.”

Simon: Yes, yes.

Paul: And who are some of the people on that and also what are their roles?

Simon: So basically, there are three founders. And we each cover distinct areas of the business. So myself, I cover a little bit of the technical stuff, with my background, obviously, but I’m also in charge of the actual general management of the business itself. So I have an MBA as well that helps towards that. So basically, just the general running of the company’s accounting stuff.

Paul: Day to day.

Simon: Yeah, the day-to-day stuff. Then we have a couple of other partners, the other founders. One is a technical guy who has been 25 years in the industry doing radiation-hardened MOSFETs, which is a similar product. It’s not the same but a similar product. So we call him the chief radiation officer.

Paul: CRO?

Simon: The CRO. The CRO, yeah. So we have our product portfolio, which we’ll get into a little bit later. It’s very much radiation hardened, so we wanted to make an emphasis on that. Therefore, he got that title. And then we had the other founder,Jim. He, basically, is an industry veteran. He’s been through many different larger companies. He’s had his own small company as well, a sales company. And he’s in charge of sales, marketing and sort of like the product strategies.

Starting a Company From Ground Zero

Paul: I see. So now is this your first startup from ground zero?

Simon: Yes, from ground zero, yes. I’ve had other businesses, but from ground zero, this was the biggest bite I’ve taken out of the apple.

Paul: Okay. How is it? The, the entrepreneurial side?

Simon: Oh, the entrepreneurial side? It’s good. It’s good.

Paul: You like it? So you get energy from that?

Simon: Oh, absolutely! Yeah, I would never go back and work for anybody.

Paul: Yeah. I like to say that people don’t understand entrepreneurs very well, but you wake up every Monday, and you’re not employed. You don’t have a job. If you don’t get up, nobody is going to do it.

Simon: Absolutely.

Paul: Do you find that to be the case?

Simon: Absolutely. I think sometimes, I don’t even go to bed. It seems like that.

Paul: That’s a good way to put it.

Alright. So you’re in New England working for a company that sort of brought you over to help them. What came across your desk, or was it you had an epiphany or that said, “I’m going to go in and start a semiconductor company in this particular technology”?

Simon: We’d seen this in the industry. It had been around in the industry, but it was very marginal on the outskirts of technology. And then there was a reorganization we did in the company that we worked for. All three of us worked at the same company.

Paul: Oh, okay. That’s good.

Simon: So there, there was a reorganization, and it just felt like the right time. So it was we didn’t want to go in the direction that that company went into, and we wanted to follow this path.

The Risks – Believing in Your Company From Day One

Paul: Right. But, I mean, there’s a lot of technologies that come out that don’t prove out. Was there a huge risk, or were you at the point was it past the tipping point of it proving out?

Simon: It had gone through its initial preliminary stages where you knew it was going to work. I’m not sure the tipping point. There was still a lot of work that we’ve done in the last two years that’s maybe taken it to the tipping point now.

Paul: Okay. But you took a big risk.

Simon: Oh, yeah. Absolutely.

Paul: So, because it could have been, “Oh, we can’t solve these problems.”

Simon: Yes, absolutely. It could have been. It was a major risk. Ask my wife about that. She’ll confirm that.

Paul: You did what? You did what?

Simon: Spent the college fund on what?

Paul: Well, that’s key to….Or just everybody’s entrepreneurial experience, there’s a point at which it looks like it’s never going to work. And you persevere through that, and hopefully it will work, and then hopefully it’s scalable.

Simon: I don’t think that that’s fully the case in my case at least. I believed in it from day one. If you don’t believe in it, you don’t take that risk.

Paul: Sure. But you, but that risk is there.

Simon: Oh, absolutely.

Paul: You may have an irrational belief, but you proved out now that it was rational.

Simon: Absolutely.

The Execution of a Business Idea

Paul: Okay. So you’re past that failure point. Imminent failure point. So now it’s the execution of developing it. So where are you in that? We’ll get into what the products actually do, but you took an idea that was a concept or a set of processes probably, and refined those so that they would produce what you had hoped they would produce.

Simon: Correct. It was essentially that the guy that we worked with, with Efficient Power Conversation, he has a product. So we thought we can make that product better and specifically direct it towards the space and high reliability market. And that’s a market that the EPC was not interested in getting into fully because they didn’t want the hassle of supporting, a Boeing, a Northrop Grumman, any of these large prime subcontractors that ask for reams and reams of data.

What on Earth is Going on In Space Right Now?

Paul: To what end? Alright, well first of all, there’s a bunch to peel back here for the general listener I think. So, you say you supply stuff to the space industry. You didn’t even say aerospace.

Simon: No. It’s space.

Paul: Space. Now I am pretty technically savvy and interested in it, and I follow SpaceX and all this stuff. But that doesn’t seem to be that many things going into space. Or maybe I’m just ignorant.

Simon: Oh, there are, there are tons of things going on in space at the moment. Now is space’s watershed moment, so it’s the space revolution, I would say, at the moment.

Paul: And but, this is for near-earth objects or is that the words?

Simon: It’s LEO, low Earth orbit. So they’re the ones that are closer. And then there’s medium Earth orbit, and then…

Paul: So is this like tens of things are going on in space or hundreds or thousands or tens of thousands?

Simon: You’d be surprised how many launches. There are launches every week I would say. Yeah, yeah. I would say that satellites buzzing around up there at the moment, it’s impossible to put an exact number on them. And this is in the public domain. There’s a number of constellations that are coming out now. So take, for instance, a commercial constellation called OneWeb. You may have heard that they just broke ground down in Florida. They have a conglomeration between Airbus… Richard Branson’s involved in it. There’s a number of things. Softbank has funded this. And there’s a revolution at the moment in the space industry. And OneWeb is just one of the constellations.

Paul: And by constellation, you mean multiple satellites working together?

Simon: Absolutely. So it’s like a network in space essentially. So there are a number of projects for this type of constellation. So they would launch nearly 800 satellites at a very low altitude, so the low Earth orbit.

Paul: What is that? Just for listeners.

Simon: I wouldn’t be able to give you the actual height. I could look it up. I don’t have it on the top of my mind, but it’s basically the closest you can get to earth without actually falling through the atmosphere. So it’s not very high. That’s why they need more to cover more areas of the globe.

Paul: Because the distance isn’t as far.

Simon: Yeah, so that the longer ones, the higher altitude sate—, satellite such as the geostationary. They would stay over the same point, but they would cover more because the cone of coverage comes down and covers more area on the earth’s surface.

Paul: And I know we’re getting off track here. But why wouldn’t I put up a higher one?

Simon: It’s more expensive. Firstly, you have to get it higher.

Paul: Really that’s the expense?

Simon: For rockets and it’s exposed to more harsh atmospheres up there. So you get more radiation. It’s closer to the radiation sources. It’s closer to the sun and so on.

Paul: So there’s like a sweet spot.

Simon: I wouldn’t say there’s a sweet spot.

Paul: Or many sweet spots?

Simon: The higher you go, the more radiation hardened you need. The lower you go, the more tolerant you can be with radiation.

Paul: I would have never thought. Okay. So that’s a cool thing to sort of look up, is to go and look at all these different projects that are going on for all the lower Earth orbit stuff. So… Okay, so there’s a lot in the space world.

The Market for Satellites and Small Constellations

Simon: Yeah. So I mean, basically, there’s been a shift from the small constellations with geostationary satellites, with the high altitude, and they have to have lifetimes of 15-year mission expectancy.

Paul: Yeah. Because you can’t call a repair…

Simon: Exactly. You can’t send a guy over there with a wrench to fix it.

Paul: It’s very expensive. It’s just too expensive to do that, yeah.

Simon: So basically, the, the commercial level of satellites at the moment, which is all these LEO constellations, these very commercial constellations, is changing the market. It’s revolutionizing the markets at the moment. So it’s a little bit like Henry Ford did with cars, you know. You could make tons of these things. They’re almost, you can use them and throw them away. That sort of thing.

What Are Constellations Doing Right Now?

Paul: I see. So let’s take another detour. We’re getting further away. But what are they doing with these constellations? What application?

Simon: So, one of the typical applications is communication. So it’s basically internet via space. You may have heard of project Loon from Google. I’m not sure whether that’s still going on or not with balloons. They wanted high altitude balloons. So this essentially uses these new commercial constellations. They link together, and they form a network. It’s almost like the old cell phone towers, if you like, but it’s, you know, with no towers and no wires on the ground.

So it can give absolute coverage all over the globe for internet access. You get your internet access via satellite. So in the case of what’s just happened — the hurricanes down in Texas and Florida and the Caribbean — it doesn’t matter if your cell tower falls over.

Paul: Yeah, it’s a paradigm shift.

Simon: So it’s a major revolution in the way that we communicate as well.

Paul: Okay. Is this really the differentiator in your products, the radiation hardening of it?

Simon: I would say between our products, which is radiation-hardened gallium nitride, and normal gallium nitride, absolutely. It’s the radiation hardness. But between GaN, per se, and other technologies such as silicon, we have far more superior performance. We have faster switching times and lower losses.

What is a Semiconductor?

Paul: So what are you making? I mean, are they transistors? Are they integrated circuits?

Simon: So we make transistors. Everybody is familiar with the transistor radio. Basically, it’s a switch where you turn things on, and you turn things off with a piece of semiconductor.

Paul: 2N222.

Simon: There you, there you go.

Paul: 22-22.

Simon: That’s an old silicon technology, which is still going. So there’s nothing wrong with it.

Paul: So, okay. So for, for our listeners that aren’t electronics people, it’s like you have a light switch. A transistor is a switch. Check me on this.

Simon: That’s correct. Yeah.

Paul: It’s a switch. But the toggle is another like electric field. So you connect something to the toggle, and it lets it flow or not flow?

Simon: Exactly.

Paul: And that’s why it’s called a semiconductor because it conducts under one circumstance and then another circumstance it doesn’t. Hold on. So, I had thought everything moved to ICs.

Simon: No.

Paul: You know, with millions of transistors on the ICs. So you’re saying that there’s still applications for just individual transistors.

The Market for Semiconductors

Simon: Yep. Absolutely. We call them discrete components so that there’s absolutely a market for that at the moment. And the way that there is a market for that is it depends on the application. So the ICs that you’re talking about will basically be digital functions, like processors or things like that.

Paul: Yes, no.

Simon: Absolutely. So what we do with our discrete devices, the individual transistors, is that we manage the flow of power. So we are dedicated, really, towards providing solutions for the power management of the satellite. So to give you an idea, you’ve seen the wings of a satellite with the solar panels. So they gather energy from the sun, feed that through to a converter on the actual body of the satellite itself, and then basically, that raw energy has to be converted into — I don’t know — five volts or 3.3 volts or a test that amplifies something.

Paul: Voltage regulators.

Simon: So basically, you can use our discrete transistors in all of these power-supply-based circuits.

Paul: Okay. So I could use silicon to do that.

Simon: You can use silicon.

Paul: So if we were sitting here on Earth, which we are, and we were going to build a power supply that converted the sun energy to 5-volt, 12-volt, whatever it might be, and regulate that so it doesn’t change and we could build it with a lot of different things. I could go out and get an IC to do that. But when I fly that into space, certain problems start to happen.

Simon: Yes. So when you go into space, you have to take into account that the parameters of these transistors can change with… If you receive doses of radiation. There’s no atmosphere there, so radiation can easily attack your electronics. So that’s the first advantage of using our products, which we’ve modified sufficiently so that they are radiation hardened.

Paul: And is that just the case of it, or is it actually the actual innards of…?

Simon: It’s the innards. The innards of the semiconductor itself.

Paul: So they’re not affected as much by radiation.

Simon: Correct. That is absolutely correct.

Paul: And, is it like a 2% difference, or is it like a 50% difference?

Simon: It’s like night and day.

Paul: So it’s a game changer.

Simon: Yeah, oh absolutely a game changer.

Paul: So what did we do before this technology?

Simon: So before this technology, we had silicon. Silicon, basically, which has its limitations, so you have to do a lot of derating. You have to use them way below their stated voltages so that the radiation doesn’t really affect it. So you have to over-design these things.

Paul: And make them bigger, I imagine.

Simon: Make them bigger. Size gets huge.

Paul: Probably more shielding and things like that.

Simon: Yep. You can put shielding around the actual circuitry itself and not just the component but the circuitry itself. And there’s another element to using gallium nitride as well. Not only have we managed to achieve radiation hardness with it, but intrinsically, the material itself, the gallium nitride material, is far better than silicon anyway. So just going back to your previous example on the ground, if we wanted to build a power supply or a converter or something like that on the ground where we don’t even worry about radiation hardened effects, we could still make those circuits way more efficient.

Paul: So actual efficiency. I’m building a power supply that’s 50% efficient, yours would be 60%? I know there’s a lot of parameters, but I’m just saying…

Simon: There’s a lot of parameters, but we can easily outstrip the state-of-the-art silicon.

Paul: Well, that’s going to be a huge issue in computers. The biggest problem in computers is getting the power to them.

Simon: Yeah. Absolutely.

Paul: And so there’s a market there as well.

Wireless Charging With Gallium Nitride Technology

Simon: You will see that some of the commercial applications that EPC is, is pursuing are smaller bricks essentially, power supply bricks. The smaller ones of those. Even the remote charging. You can do remote charging because gallium nitride switches way faster than any silicon technology. So you can get the wireless charging. It’s also advantageous for things like LIDAR. So it will revolutionize the autonomous vehicles because it can scan, and it has vision systems that are way more detailed than the standard silicon-based technology.

So it really it’s a GaN revolution at the moment. It’s a GaN revolution.

More Episodes:

You’ve been listening to Part 1 of our interview with Simon Wainwright. You can listen to part 2 of our conversation, here! We’ll be talking about the future of the space industry!

Also published on Medium.