 So, we had the HP, and here is showing a picture of a simulation of a supercomputer in space. Is that what it is? You're doing a supercomputer for space missions? Correct. We placed a supercomputer in space so that on our mission to Mars we'll have some onboard computing capabilities. So, right now, is it on the ISS? Yes. We have one on the International Space Station. It was launched August 14th, and it was powered up on September 14th, and it's been up and running as we want it to be since then. So, a big question from my website is called, is it one of those arm-based supercomputers, or is it something else? No, it's an Intel-based two-socket Xeon general-purpose computer. It's often used in many data centers here on Earth. That uses a lot of power, right? It was using 500 watts of power, all coming from solar cells, so it's the most energy-efficient system out there. It's free electricity and free cooling. So, that's actually not too much power? Not too much power, no. But it is doing one trillion calculations per second. One trillion? How much power? 500 watts. 500 watts. A regular gamer with a desktop that runs at full speed, he runs more than 100, 200, right? He runs more than 100, that's correct. So, you just have two of those gamers. Two of those gamers in there. Two and a half. But I'm not generating any graphics, and I have no keyboard, mouse, or monitor. This is real science work and real benchmarks. So, what is so important? It's going to be very important for the Mars mission, right? Correct. You don't want to wait 8 or 18 or 16 minutes or I don't know how long it takes for the signal to come back. Oh, it's 24 minutes one way. Best case. 24 minutes back. Yes. For a signal. No. No? No. It's further out there. That's when Mars is on the other side of Earth. Other side of the Sun compared to the Earth, right? Yeah, 24. If it's on the same side, it could be shorter, right? No, it runs about 24 minutes and longer. Yeah. All right. So, that's too long. That's too long. If something goes wrong, you're going to need to do the math, the calculations, to follow your procedures much faster than relying on the support staff back on Earth. But not only if it goes wrong, you need a real-time feedback so you can keep it pretty. Yes. Otherwise, it's going to take lots before you get it to keep going. Correct. You're going to be able to take the latest and greatest commercial off-the-shelf stuff with you, and that's this test. We took it right off the factory floor within a short period of time before it had to be delivered to NASA for launch on SpaceX 12. So, you are the Elon Musk rocket. We were delivered by Eon Musk rocket, yes, SpaceX 12. Did he examine himself personally, the cargo? Not that I know of. He didn't check it. He didn't sign it off. Not that I know of. NASA signed off on it, for sure. Did you see the rocket launch? I was there for the rocket launch. Were you nervous? Nervous. A few seconds. Extremely nervous time. The launch is very, very exciting. The landing is pretty exciting, too. It's really cool. They did the magic. The landing is within sight of the launch. Oh, they landed. They landed back at the Kennedy Space Center. Correct. That was the same amazing trick they just did recently with the... SpaceX Heavy, yes. Were you crying? I was crying. I was very excited. I was crying when I saw that double landing. But when you see your project get into space, you must be crying a little bit. I was choked up in teary-eyed. Another significant thing about the SpaceX Heavy launch is, while that was going on, we were doing repairs to our system on the ISS. What's that mean? That's two totally separate space operations going on, independent of each other. It's no longer one thing that is an experiment that is a test by a government entity. It is a marketplace now. Space is a marketplace. So, can we start from here? What are you wearing right here? I'm wearing a lapel pin delivered to me by the ISS office. This is the ISS? It's a huge, actually, thing. The ISS is huge. Yes. It's a little bit longer than an American football field or a little bit larger than a soccer field. So, they're busy right now every day? Busy every day. We're in constant contact with it every five seconds. We have an hour a day of allocated time where we can actually interact with the payload and do things live. And then once a week, we're in communication with NASA about a review of the past week and what we're going to do the next week. So, basically, the technicians that are the astronauts installed your gear. They switched it on, the cable, everything. Now you can remotely use it from Earth. Correct. Whatever you want, right? Correct. One hour per day at least. Yeah, correct. Just like you get into Google or log into your email, et cetera, I log into a supercomputer in space. Log into space. It's pretty awesome. It's pretty awesome. That's cool. Every time I do it, every day. Is this the only supercomputer in space? That is correct, yes. We're doing one trillion calculations per second called a terraflop. So, are you trying to kind of assimilate, emulate scenarios that could happen at the Mars mission? Is that what you're doing with it? No. The primary purpose of this very first mission is to prove that we can last for a year. And so, therefore, we're running a set of internationally recognized benchmarks that stress to the max every aspect of the computer. Compute, memory, storage, IO, networking. We want to stress every component as much as we can in order to make sure that when we go, we need to know. Because we're going definitely in 2022, 2024 with people, and 2022 with just cargo. Cargo, right. That's the plan, right? That's the plan. Yeah. So, there's several people that have several plans. But by 2022, in 2024, there might be some new chipsets, some new server chips. So, maybe ARM is going to be great. It could be, yes. It's called the HP Moonshot for real. HP Moonshot for real, yeah. A little bit, right? A little bit, right? Yeah. A Mars shot. A Mars shot. An HP Mars shot. That's all the ARM stuff. Correct. That's all ARM. Could you be considering that? Correct. We just wanted to make sure that the electronics could last a year. And so, we took the most common high-performance computer server available. And that's a two-socket Xeon. But as that market evolves, we, again, of course, want to test those other options. I'm sure when they send those first missions to Mars, there's going to be a bunch of Mars processors in the rocket. I don't know. There's all these things going on. I don't build the rockets, right? It's pretty cool. Yeah. So, this happening and HP is playing a big role in space? Yes, we are. And our partnership with NASA is very strong. We've had a partnership with NASA for many, many years. Their largest supercomputer is a very large HPE 8600, acquired when HPE acquired Silicon Graphics. And we continue to grow that system and push the bounds of high-performance computing here on Earth. And the lessons we're learning are transferring into space.