 And we're here with Visionox. Hi! Hi, my name is CCD working in Visionus and here I would like to introduce our new technology, VIP. VIP stands for Visionus Intelligent Visualization. We use photolithography to replace the conventional FMM. So in VIP technology we can have better performance and for example we can have larger aperture ratio and we can have higher brightness, longer lifetime and also the more competitive cost. So in these exhibitions we demonstrate a 7.9 inch foldable AMOLED used fabricated by VIP. But you can come here to see the prototype. Thank you. So you say here potentially four times brighter, six times longer life, higher pixel density. All this is possible because of VIP? Yeah, because of VIP. Because we use photolithography so we can remove all the limitations from the FMM. So no matter in aperture ratio and lifetime, we can improve it. And to combine with our other new technology, higher pixel density could be achieved. So we're talking about higher pixel density, brighter, longer life, no burn-in problems? Yes. Less burn-in problems? Yeah, because longer lifetime. So combined with 10 times we can have six times longer so there won't be the burning of the patients here. How far is this from mass production? We are targeting to have production in next year. Next year? Yeah. What is it going to change in terms of price? Is it more expensive? I'm not sure but we can provide more value to our customers. No matter in the image quality or the lead time and also for the pixel design. For example we can have very new ID design. For the shape it could be customizable. It says lower comprehensive cost? Yes. How is possible? Because we remove FMM so the cost of FMM could be reduced. So you just take it away at that cost. Is this implemented in the foldable display? Yes, this one is foldable prototype. We just input the sample into the unmetric V. So here you can see the foldable behavior. So this is the one? This is what you change? Or do you change many different things? This one, patterning technology. We use photolithography. And how do you optimize photolithography? Is it cutting edge, photolithography? Yes, that's conventional photolithography process. But we design a very specific process flow. So we can prevent all that damage from the liquid. Then we incap all the pixels at first and then to have the photolithography. So this is the first time you show this? Yes, yes. This is our first time to demonstrate this technology. In this exhibition we see similar demos but our prototype will be the best one. No matter in the size or in the pixel density or other performance aspect. Nice, cool. Alright, thanks a lot. Maybe I can walk around and have a look if we can complete the booth tour. Do you want to do the booth tour? Yeah, cool. This is a rollable laptop display we've been built for the future customer. We've been trying to enable our customer to design different forms of a laptop in the future. And we can see there's another one we can show today. This is a very beautiful display. Can I film behind? Yeah, sure. So it just rolls up. Do you actually show it rolling at the show? We can roll this up. Maybe not now. Later? Later. Alright. Which one should we go to? Yeah. And for this area we do have our transparent OLED display which we can support up to 50% transmitters which can be applied into automotive scenario. We can do both glass-based in flat shape and also PI-based in curved surface. People can vote. People's choice. This is for the future of self-driving cars. You just have the whole window shown up at display. Advertising and the contact and delivery information, all kind of information you can do. And it can also see a lot of people to see from the inner side. So if you don't mind having a lot of advertising on your future self-driving Uber ride, then you could get a free ride because the advertiser will pay for the whole trip. Maybe. Maybe in the future, yes, of course. Alright. Transmittance. This kind of display can be also applied into the merchandise shop which can allow people to see different advertising like the dress. You can try it on the dress and you can see something inside. This has already been applied already in the market. But we can do it in different substrate, both glass and CPI. Nice. Maybe you can put it right in the middle. In the middle? Yeah. This is an application scenario. We built for the medical box. It can be folded in both sides. It gives a very beautiful vision experience. What does a vision ox mean? Vision of X. X means the future. We want to see the vision for the future and promote the human experience on the vision. Especially the displays. This is an experience for the flexible displays. As you can see from the top side, it can be shaped into a different curve. Even a multiple curve in one panel. How is the performance on a display like this compared to a flat one? Actually, it can give us more design capabilities for electronic devices. As you can see in the front side, the color gamut, the response time and off angle color shift performance is much better than traditional LCD displays. What are we seeing here? We're looking at a flexible tablet display. We've been developing it now. So it's a plastic front. It's not glass? It's plastic based. But it's used in a flat shape. But this is a flexible display. Does that mean it's more durable? It's less likely to break? Yes. It's literally non-breakable because it's PI based and when the device falls into the ground, there's no crack of the panel. So this is a solution for safety, maybe in the future. Right here in the middle side. I see a dynamic slideable. Yes, it's dynamic slideable. All right. We have some more foldable. Is it actually folding and rolling during the show? For now it's not. But it's capable of doing that? It's capable of folding in both directions. Okay. You just need to power on the foldable mechanism. And what do we see here? For this one, this is a rollable solution demo. And it's more like a roll of paper that you can spread it, you can roll up. All right. Okay. So later maybe you show it off during all the rolling and folding? Yes, of course. And this is a demo for driver's scenario. It gives a very, seemed by the very broad vision of the display that you can see. You can integrate different information onto the display for like the dashboard information and central information display and an e-mirror on both sides. And what's happened in the middle, the crease? It's just two different displays? Yes, it's a two displays. They put together and there's something in the middle. But it's to be fixed like this. It's not folding or rolling or something. Yes, this is a fixed shape. Yes, fixed shape. Not dynamic. Oh, there it is. Nice. It's dynamic, foldable in both directions. Nice. So it can fold millions of times before breaking? Yes. Hundreds of thousands? Hundreds of thousands. And is this mass production for the dynamic slideable? We are ready for mass production. Nice. This one? Yes, this is a rollable. Cool. That's awesome. I really feel like I'm in the future right now. What do we see here? Over here we demonstrate our super high frame rate display even up to 240 Hertz. You can take a close look. Up inside it's 240 Hertz display and down side it's 110 Hertz. My video is only 60 Hertz. It's going to be hard to show what I'm experiencing. But with human eye you can recognize the differences in different Hertz as the images drag along in the lower Hertz. It's more realistic I think. When you have the higher frame rate it just feels more... Smooth. What is this? Is it a secret future display? No, that's not a display. Yeah. And? And with more advanced... With more advanced OLED material generation upgrade we can significantly lower the power consumption and try to give more lifetime performance into our display. Is it a variable refresh? I'm sorry? No, it's not variable refresh. How do you get the lower power on this? This one is using the latest OLED material generation. So with the latest generation of OLED material the power consumption can be lower and the life performance can be better. And of course we do have other technologies for example like a variable frame rate and from one Hertz to 30 Hertz to 30 Hertz to 60 Hertz or even 120 Hertz. As you can see over here we have a demonstration for 180 Hertz and 90 Hertz in flexible mobile display. Flexible. Are you able to do the same Hertz for flexible and not flexible? Or is it a challenge? Yeah, we can do different Hertz but the important part is that we can... This is a demo straight there. Sorry, this is... Is this a mass production device? Yeah, this is a mass production device we built for Razer. For gaming... Yeah, this needs to do something. Yeah, yeah, yeah. Yeah, this is not cool. Logging. Okay. Nice. And for this area we can... We introduce our... In the ALT technology we can allow... Lower as lower to 30 or even 1 Hertz in our LTPS panel. Right. Yeah. So this refresh is only once per second. Yeah. Like for a clock. Right. Yeah. 5 Hertz. Yeah. No. This is a regular LTPS based OLED technology but with our ALT technology we can make it as low as to 5 Hertz or even 1 Hertz without observable flicker. What's the power saving when you do 1 Hertz? How much difference? Is it 60 times less power than 60 Hertz? Yeah, when you do... Or how much less power? When you do like in a certain color and in a certain size, the power ratio we can save from IC level can be very significantly lower. And what do we see here? We're looking at the HLEMS technology. This is our new light extracting technology with very high efficiency and low power consumption. This is mostly for the power consumption. We made this technology to allow our customer to give a longer lasting battery life. And so the customer and user can have a better experience based on their devices. Nice. Yeah. All right. And what's the last demo you have there? For this one, we built our AOT technology into phone size which can support as low as 30 Hertz. As you know, lower Hertz, lower frame rate will have lower power consumption. All of this can contribute into longer battery life. It's possible potentially, as I see here, it's 20%, something like 20% longer battery life. Yeah. Because you have variable refresh for the whole device. In this area, we have our bezel-less technology. For example, if we look at this watch size display, we can minimize the border down to 1.24 millimeter. And how do you do that? By optimizing the process recipe and also the design by using the cutting edge technology of our industry. And if you look at this phone size panel, we can do less than 1 millimeter border both for upper, down, left side side. And even for the corner, we can do 0.5 millimeter border. This is the ultra-thin, ultra-border technology. Is it the thinnest bezel in the world? Yeah, we don't want to compete with any company in the industry. We want to compete with ourselves. We want to give better and better experience to the customers. So any user brand, the brand phone companies can design better ID and give better experience to any user. This is a bezel-less technology. And it might not be easy to capture the... If I look at the upper side, when the fruit falls from the upper side, we bend the panel to the rear side. So as you can see, the fruit falls from the top side. There's literally no bezel, because we bend the panel and extend it to the rear side. So now the bezel is the display. Yeah, it's a bezel-less. Zero bezel. It's like the dream. People don't like bezels. Yeah, of course. And this is new technology area. We have different new technology under development. We were trying to activate the market with our innovation. This is an integrated optical fingerprint technology. We're using the high DPI solution for touch sensor in panel. Does that mean more security? Because it's higher resolution or more reliable? Yeah, most of the solutions in the market, they will give a small area. For example, even smaller than this area. So people can only use one finger to recognize the user. But with this technology, we can enlarge the area of the touch sensor area. So you can put both of your fingers together into one area so you can recognize it's more safe. So you can have a security functionality where there's two secret fingers. You don't know which finger and then you have to put those fingers and then you log in, both at the same time. These two fingers can come from two different people. This is a potential application scenario. And this one is a 3D MVC solution. Our technology can support 3D in-depth camera in the rear side of the panel. Which means you can use the panel as a full screen area if you're looking at the display. But if you want to look at the camera, there's some area that can be tuned. And the camera from the rear side can emit light through the panel. And we can put at least two cameras in the rear side. You can give the 3D in-depth recognition on the face. A human face. Yes, this is a TOF type of... It's a time of field stuff. I see a lot of dots all over my face. So it knows the distance to everything. Cool. And for this area, we do have integrated our antenna on display. If you look at the video, this is about a 10 second video. There's an antenna layer integrated in the structure of the display. And we give more solutions for the smartphone to support 5G connection. Are you able to do phase array design on the LCD? Yes. I mean on the OLED. How do you do? Yes. Let's do a phase array antenna. Phase array antenna? For 5G millimeter width. OLED. Yes. Phase array. Yes. So you can connect this to the satellite. Is it Starlink? You can do Starlink antenna? Yes, in the future. It depends on the frequency. So you can see the beam is staring. It's a phase array. Yes. The mic is closer. Yes. So the beam is a phase array. And then with this display, you have the best signal. Yes. So it's going to be the best 5G or the best whatever. Yes. Even Wi-Fi, Bluetooth, everything. Yes, connecting to even satellites. Sorry, let me give you my mic. What is the potential antenna? Potential antenna? Yes. What it can do? Yes, actually currently we do the 5G millimeter width design. So it's a phase array. And you can do the beam staring at millimeter width frequencies. Yes. So for something like Wi-Fi? Yes. 5G millimeter width? Yes. So with this display, the phone will have the best signal in the market. How is it compared with the built-in antenna? The built-in? On a normal phone? Yes. How is the signal? Can you combine your phase array with the normal antenna? And combine together to get even better signal? We can deploy several something like this AOD designs. Yes. So we can have something like the selection algorithm to choose the best one to do for the Asians. So if it's built-in antenna sometime and display antenna sometime both together? It depends on the algorithm. Because when they work both together, the power consumption maybe is an issue. So for now, we just choose one of them. And you were saying this could potentially also work for Starlink? Maybe. Something like that. Satellite? Or you only want to do 5G? Everything is 5G in the future? Actually everything is possible. But it depends on the frequency. Because frequency is related to the antenna size. Because this is a big antenna. You get the full display. No, no, no. It's a big compared to normal antenna on the phone. What did the normal antenna have like in every corner? What did they do? Yeah, you are right. But the thickness, the height, the antenna height actually is very limited. The antenna height is very important. So the area is not the first priority. The height should be the first priority. So it depends on the frequency. So if the antenna frequency is higher, so we can... Yeah, we need a lower height to do an efficient radiation. What does this have to do with the... When people make sound come out of the display, they vibrate it very little bit. Is this something to do with that or nothing to do with that? Nothing to do with the word. How do you do an antenna with the display? I have a hard time to understand. You can see. We just insert an antenna layer in the form of metal mesh. Yeah, this antenna layer. And then we can design antenna patterns on the layer. It's very thin. It's not possible to make it thicker. For antenna guys, we prefer thicker substrate. But for display guys, they prefer thinner display. So it's a fight? Not fight. We have to follow layer requirement because this is a display. Because sometimes, the phone is like, let's say, 0.8 cm or 1 cm thickness. So the whole thickness should be antenna. The whole thickness? Why not? You mean all the way through the electronics or something? I don't know. Does it make any sense what I'm saying? You have to stay on the display. You cannot connect with the... Expand your mesh. I don't know. Sorry. I don't know what I'm talking about. Okay. For now, we prefer on the display. Yeah, it has to be on the display. Yeah, for efficient radiations. How far is this for mass production? Okay. Now it's in something like a research stage. And hopefully, maybe... I don't know. Yeah, actually it's not so certain. Maybe we hope, maybe we think... Because this area is... Five years, something like that. This area is only for the new technology introduction. Yeah. And all the experimental or the fundamental... We've been conducting research into this specific area. So we were trying to differentiate the shortage from the advantage and try to industrialize this technology in the future. Is it the first time you show it? Yeah, I believe so. For visionals? Yes. Because I heard... These guys, Merck over there... They were doing that for LCD. They talked about LCD factory to make an antenna. But OLED is different. Yeah, it's quite different. But the most important thing is that we do the integration. We integrate antenna into the display. That's the most important and the most meaningful something like things to us and to display industry. Nice. All right. Thank you. Thank you a lot. Yeah. All right. Thank you. All right. I think this is all we have this year for the SID. And welcome to our booth. We've been here waiting for you. Can you explain a little bit about your company? Where are you based? And where is a different R&D happening for this? Where is the factory? We're a company dedicated to OLED technology for over two decades. And we do have three panel line in China. Three module line, another line in China, covering from north side to the south side of China. And also, our research team and the factory team are based in China. But we're opening our US branch in the future. And we'll be launching our sub-company later this year. And we're supporting our company to serve all the global customer in the future. Is it possible that Visionox goes and does TV? Or you're only focused on mobile sizes? Yeah. We are planning covering different sizes in the whole industry. And for larger size, we do have plans in the future with higher generation of panel production line. Cool. Okay. Thank you. Hello. I'm MrBeast. No, I'm not MrBeast, actually. But if I was MrBeast and if I was sending you a bunch of money, I would use Wwise. 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