 So here's the magic leap here with the analogics. Hi so who are you? Hi I'm Gratius Defan with Analogics Semiconductor. You're looking at the magic leap AR-HMD. So your chipset is inside? Yes, our Slimport ANX7530 is inside. To do what? It basically does the the conversion from Meepee to DisplayPort and displays on the PCB inside the VR headset. Because your solution is great for VR. You have some you're showing something about there? We are showing. And that's kind of around here. Is it this kind of solution you have inside? Exactly. This is, we announced it's actually a COVITEX. We announced it's a COVITEX in Taipei and back in June. It's our second generation Chicago chip that you just saw that's inside the magic leap headset. And we expect a lot of VR manufacturers, headset manufacturers to produce this. Why did you use this and not what they have before? What's better about this? We increased, well the resolution is higher. The package is also smaller. So it allows for cost savings on the bomb. And the higher speeds, higher resolution. Less heat maybe? Yes so every the whole performance of the system is improved. You get higher resolution, faster refresh rates, lower power and with a much smaller package. Up to what resolution? Is it very high right here or? Yeah this one I believe it goes all the way up to 4k for both eyes. Nice and over here you're showing the retimer systems. You also showed this as COVITEX right? We showed this as COVITEX. We announced our 7440 family going into production in a whole bunch of notebook, PCs, arm and windows. It basically shows a cascading daisy chaining process. You have... What about here? It is a one-crumb book? Well yeah it connects basically between a source device and an external display. You have a system that goes from a USB 3.2 to a display port out of mode. So that means this MacBook has four type C's and they can all do power, they can all do display, they can all do everything. So just to make the type C port universal and simple, you provide a solution to enable all this? Well what the retimer does, it allows now that the speeds are so high they go all the way up to 10G. It's a signal conditioner that allows the content to go throughout the whole system with no losses, visual losses in the actual quality. And you were in this Chromebook right here, an Intel Power Chromebook? Yes, with the Chromebooks and others with ARM too? Yes, with our NSA429, a whole bunch of Chromebooks from Acer, from Lenovo, Asus, Samsung HP, so they're all using our solution. Here you have a retimer solution, just like you saw in the daisy chaining design for a smartphone. Yeah. And it allows for these high resolutions 4K by 2K with concurrent display port and USB 3. So this is like a type C dock for the phone and this dock does all bunch of stuff just from one cable? This is the PCB version but you normally see this inside a phone. Inside the phone? Inside the phone. Okay, all right. And here's another Chromebook. This is another Chromebook design. It's using our Centiphone 47. It's a PD 3.0 single chip solution in a whole bunch of Intel Gemini Lake-based platforms. Nice. And what's he working over there? He's actually showing, we're showing here a VESA display stream compression, a DSC compression using one of our chips. It's a timing controller that goes inside the actual panel. And what the system shows, it basically shows you that it goes in and out of PSR every couple of seconds and it alternates between compressed and uncompressed images. Nice. So you work together with the VESA which is doing the display port? Yeah, we, yes, we are a member of VESA. VESA is the body, the central body that has invented the... One of the main members, right? We are one of the main members. Kind of the founder of the whole display port? Yes, we actually go back way back to where we want display port. We invented the display port. Pretty much, yes. And what is this demo over here? This is another display panel. This is another timing controller demo. It's using a timing control chip that we actually announced in September. It's the 2403. It's the first displayed HDR400 certified IC. This is a HDR400. What is that? This is a stand for HDR by the VESA. VESA announced display HDR a few months ago. There are a few categories and we are the first semiconductor company that has a timing controller display HDR400 certified. Because you need new HDR displays of course. You also need new HDR supported cables? Yeah, there are a whole bunch of displays out there. They all say they display HDR but now VESA has come up with this truly comprehensive testing process and categorizes actually all the displays into these three different categories. To support all the different types of HDR? Yes. HDR400, 600, 1000. So, they're different categories, different testing procedures and processes and we're very happy that our chip has come out. Does 400 mean peak luminance? I don't know the details of the actual spec. VESA has published that on their website. And this? Here we show a 8-bit versus 8.2 demo. Basically the source here is a quantum data generator. There is a difference between 8-bit and 8.2 with the FRC output. What is 8 plus 2? It's a different setting of the bit color. So analog jigs is very busy with lots of things happening? We are doing a lot of things. We are very much involved in the interface connectivity space as you've seen here in the display panel with timing controllers as well as in the VR, AR space. With all these different ones? These are all the high-end ones, right? Well, we are high-end and lower-end. So, on the lower end of the spectrum, we have the Microsoft Mixed Reality headsets that were announced last year. We're in all of them including the second generation from all sorts of suppliers like Samsung, S-Dacer. We're also in a different, this is not really VR, it's more like a gaming console. How does it work? It's two phones? Yeah, it's actually from Asus. They promote this as a dual screen. The same VR chip that you've seen in all these VR headsets is actually used in this particular application as a dual screen phone display. So, you put in your phone here and here is the extra display for it? Yes. So, it's using the display port output of the Type-C that is supported in the phone? Yes, it's the same. It's a display port 1.4. There's a receiver that has four lanes and there are two single Mipi DSi outputs. So, it seems that the display port out-mode on Type-C has been very popular, right? It is very popular. How did you manage to do this? Well, again, we have been in the display port area for many, many years. We're always trying to innovate and trying to come up with different use cases to improve the user experience. And this play port right now is the only interface that can achieve those levels of quality.