 So I'm going to be talking about airborne networks and data. And what we're doing is we have a business that we've created in Christchurch, New Zealand. We founded it there. And I'm acting as the CTO and co-founder of that company. So before I start, I want to give a little bit of background of where I've come from. And what I've started is in the bottom left there is an aircraft that I created when I was in high school. I was inspired by a dragonfly insect. It's an insect that can hover and dart sideways and backwards. And I was fascinated by that and learned a lot from biomimicry of nature and mother nature. And what can I do with that in terms of an aircraft design? My father was an Air Force fighter pilot. And I just took to aviation from there. Worked at Georgia Tech, where I developed aircraft such as the XB-15, which is a precursor to air taxis. And then worked another aircraft propulsion techniques that lifted up vertically and propelled for jet engines and alike. From there, I kind of went underwater. And then I worked in the underwater space of developing underwater autonomous systems. And those were remote sensing devices that sense for different aspects. And took that technology as kind of a social consciousness of what I was working on. It wasn't enough to solve for system requirements. But what was the end goal of what I was doing? So with that, I switched to renewable energy. And for the last decade, I've been working on different sources of renewable energy, a different leg to renewable energy, that being ocean currents, wave energy, tides, energy storage, different topologies for wind energy. So I've been working with my wife, Nahal, on new sources of wave energy. And then bringing in areas that I worked in the past with the US Navy to help and develop new forms of these energy sources. So we've been using tow tanks at the US Navy to get to their codes and algorithms, as well as their wave tank tests and the like, and developing new drive trains from super-conducting to hydrostatics for larger multi-megawatt wind turbines. On the bottom is what are new value propositions for renewable energy. And I developed an underwater data center with some folks. And with that, it was the value proposition of what can we do to combine renewable energy with data centers. Some of you might be working at Bitcoin for each transaction, it's like 250 kilowatt hours, which could power a house for nine days. And if you look at overalls, 32 terawatt hours per year, which is the size of Denmark. So are we looking at building more efficient data centers or maybe more efficient algorithms? How do we work together in a holistic way to bring it together? And the challenge being, is there a way to do that commercially for developing algorithms for that? So I'll be talking about drone data as a service, Skybase, which I mentioned, we're headquartered in Christchurch, I'm glad that a lot of fellows are going there. So it's a great town, it's come a long way, and I'm really excited to be there. The topologies that we're developing for this is electrical, vertical takeoff and landing. So this aircraft can lift up vertically and fly fixed wing, it has a large range, it's electrical, it can go into areas such as hydrogen fuel cells and the like. And the remote sensing that we're doing allows for, it's basically a magnifying glass, so I can go in and go in in areas where a satellite might be 30 centimeters per pixel, we can go into two and a half centimeters per pixel. And so very detailed maps and areas for precision agriculture, I've been able to track Kiwi bird or the like with some of the RF signature and then help to help our first responders. And we're developing networks and data to bring this together and then also I'll be on the line of sight, one of the reasons of being within New Zealand is that you have a regulator that can have a collaborative approach, I can call up Paula on the phone and say, hey, I've got this problem and we can collaborate and figure out ways of path forward for wide area mapping and the like. So on the left there was a Mount Taranaki where I was able to show an aircraft that the flies, you can see the landing of it here. It's a VTOL aircraft that has a lidar and so you penetrate through the vegetation that is there. And on the right is where we're looking at city health monitoring. So this system is able to penetrate very deeply through the vegetation, maybe Dubai or diversity and other things that are there. As we are moving along there was an air, we were able to do with this system here is work with our first responders in search and rescue. So looking at deploying relay aircraft and a primary aircraft in the air with an operating center that could be located anywhere in the world. We located at CSST, which was in Central Tago, which is the Center for Science and Space Technologies, which is an area that's focused on satellite imagery. So with that able to deploy these assets and provide assets to the ground and the like. So when you look at first responders that when you lose 4G networks and those things that this would allow them to communicate with fire and police and others to help in a disaster recovery response. So on the left here is there were some recent fires in California and about 6,200 homes were lost. And part of it was the fact that they weren't scanning some of the power lines and looking where the vegetation was. And because of that, there were sparking of the power lines and ignited the fires and 40 people lost their life. So with this kind of technology, we can also look at how we can find out where that encroachment is and use machine learning. So a lot of what we're trying to do is you can only fix what you can measure. On the right is some precision agriculture where we can do 3D mappings of farms and look at the leaching of nitrogen and where do we need to apply water or where things are under distress. So the hope is working with councils and giving the information to find out where and how and what we need to do to fix some of these societal and endemic problems. So thank you.