 We're talking about the latest 5G demos that you have. Yeah, so we have two of our prototype systems that we've built to align and be based off the 5G new radio. That's the standard that's being developed within 3GPP. Behind me here over on the right, or my right, we have our millimeter wave demonstration. And what we're doing here is utilizing some of these higher spectrum bands, bands above 24 gigahertz. Specifically in this demo, we're utilizing 28 gigahertz. And what we're showcasing here is that we can actually enable mobile deployments at these higher spectrum bands that were traditionally used for point-to-point, fixed type transmissions. And with those higher bands, you get propagation loss and blockage. And so a lot of these new techniques that we're bringing, these advanced antenna techniques, we're enabling to actually do mobile deployments. And we're showing things like actually being able to be in a vehicle and do handovers between base stations. So like your typical mobile type deployments at these higher spectrum bands. And the reason why we want to use those high spectrum bands is you got lots of bandwidth up there and that's so we can enable applications like streaming 4K video to your phone. So how do you do that? How are you able to follow the card? Yeah, so with some of the advancements that we've had in antenna technology, what we're doing is with these millimeter wave bands, you can pack a lot of antennas into a small space. And so then you can use beamforming to actually direct the RF energy at the specific user. And then with all these advancements that we've had in silicon processing, we can actually track the user in a real-time setting. Are you showing that this is simulating what's going to happen in the future? Yeah, so this is our hardware prototype system. So again, we're in the R&D phase of 5G today. So the specification for 5G hasn't been set. So we build these prototypes very early on and they're built to kind of flexibly track the standards process. And so ultimately this will become what actually goes inside your smartphone today, our smartphone of the future. But this is built to track the standardization and move towards commercialization. So in 835 you're talking about the X16 modem? Yeah. This is for one of the next ones? Yeah, so we talk about the X50 today, which is our 5G modem family that we're now in development. X50, as we announced on Sunday, expanding that family to support 5G new radio. And so the work that we're doing on this prototype system is actually going to be utilized to build, or a lot of the work that's coming out of that is being utilized to build that ASIC for commercial deployments in your premium smartphones come 2019. Right now it's an FPGA kind of system, right? Correct, FPGA DSP. And then later it's just going to be a few millimeters. Yeah, so as we do at Qualcomm we're very good at building ASICs, building modems that are form factor ready for small devices like your smartphones. Right here is Qualcomm's specialty. Yeah, this is where we start inventing the technologies that are going to find the next generation. And so we build these systems to exactly do that and start to test and validate and prototype these different technologies. And this is a different demo right here? Yeah, so this is the difference. So over here we were talking about millimeter wave bands. Those are the bands above 24 gigahertz. But bands below 6 gigahertz are still going to be very important in a 5G system. So whereas millimeter wave was more about kind of small cell deployments, more local deployments, and adding kind of a data boost to that. Sub 6 gigahertz is going to be where we're going to get kind of that ubiquitous coverage. We're going to be able to service a lot of the variation of use cases that we're envisioning with 5G, everything from your smartphone, but everything to connected cars, drones, IOT are all going to be utilizing that sub 6 gigahertz bands. So what we're showcasing in this demo specifically is some of the, as the standard is progressing, we have implemented some of the designs that that standard has accepted in this prototype system. And then we actually have a live prototype system operating and showcasing it here based on the 3GPP design, implementing some of the advanced technologies like Massive MIMO, which is basically putting a lot of antennas in the base station in order to be, to increase both coverage and capacity of a cell. So you need to add more antennas in the base stations. And there's millions of base stations. And there's going to be a million fans. And the world is pretty big. That means a lot of activity is going to happen in the next couple of years. Yeah, a lot of activity to get from now until 2019. Things need to get installed. Things need to get installed. We announced, Qualcomm announced with a lot of our partners, trials starting at the end of this year. So as soon as the end of this year you're going to see, based off that 3GPP standard, actual trials and systems being implemented within the network. And that means a lot of Qualcomm chips. A lot of Qualcomm solutions are going to be shipped. Yeah, so now we're not, you know, beyond just the smartphone where we ship a lot of chips today. We're talking about 5G being able to be in all sorts of different devices and offering all sorts of type of services. And Qualcomm is also at the base station? So Qualcomm is more on the device side. We also do small cells, which are the smaller base stations that are more local type environment. But Qualcomm did announce some ARM chips. They're going to be powering some servers. But this is a different kind of trade show maybe. Yeah, a different kind of trade show. This one's more focused on the mobile. And so that's going to be lots of new, and the 3GPP is, the whole industry, and Qualcomm has a big role in there. Yeah, that is, the 3GPP is developing the global standard for 5G. So this is going to be a unified standard across the world. And so yes, Qualcomm plays a very important role in both contributing our designs to 3GPP and then building chipsets based off that 3GPP specification.