 Hi, my name is Bob Dunhouse. I am coming to you from the Tianma booth here at SID 2023. First display I'd like to show you is a micro LED transparent display. So, this is in your new display area? That's correct. The new technology display area. And how's the performance? The transfer series is very good. It's 70% transmissive. With a low reflection ratio of about 10%. Alright, so this is going to be all the future self-driving cars on the windows and everything? That's one potential. Anywhere where there's glass, I believe that it could be applicable. In every home? Every window? Yeah, I mean there's many ways to implement it. This is a micro LED? Yeah, this is another micro LED display. Very similar to the one we just looked at. However, it has a regular liquid crystal display laminated to the back of it. And what we're able to do is control the transparency of the display. Actively control the transparency of the display. So it can vary it anywhere from one tenth of a percent transmissive all the way up to 24%. And does this demo show all the modes? It does. We'll have to actively switch them. This is not the image to look at. Alright, then it goes through transparent mode also? Yes. So here you see how it darkened? So we're at one tenth of a percent transparency. And now I'll lighten it. Now you can see inside. Now we're at 24% transparency. Nice. Is it some kind of an electrophoretic glass? No, actually it is a standard liquid crystal display that's laminated to the back of a micro LED display. Alright. No color filter on that particular back plane though. So it's been a busy display week? It's been very busy actually and very popular. Now we're also in the new technology area and this is flexible active matrix OLED displays. The display that you're looking at currently is what we call a trifle or a z-fold. And it's exhibiting both an inner and outer fold. The idea behind that would be a foldable tablet as an example. The display you're looking at currently is a 6.67 inch inner fold display. We can do an inner fold radius of about two millimeters. Alright. And is your audio foldable display mass production shipping? Yeah, they aren't. Again, this is the new technology area so they're demonstration. So it's for soon? The new technology is out there now. Alright. Alright. You want to move over? This is the consumer space. And this is a two OLED displays side by side. As you can see they're equal in image quality. The difference is this uses our CFOT technology or color film on the TFT layer. What that enables us to do is remove the outer polarizer. When doing so that we're able to reduce the power consumption roughly 30%. Makes it more power efficient. Nice. That's a big deal. It is. It is. Alright. The next is a 6.81. What they call it a quad curve display. And that means that all of the edges are actually curved. So this could help to have a better, less kind of... It's aesthetics. Aesthetics. Aesthetics. This is a 6.497 inch, what we call privacy display. So display on display on the left is your normal display in LTPS. And this is the privacy switching feature. So if you look off angle you see I can change... You can change the privacy level? Yes, that's correct. So we limit the horizontal viewing angle. Alright. This is a touch embedded display. It actually has an active pen sensor embedded in the glass assembly itself. This is just a demonstration of a fast refresh display. This usage would be for like handheld gaming where they need immediate response in displays. It's demonstrating 60 versus 180 Hertz. Nice. This is a low temperature polysilicon displays. But you're always looking to get the thinnest border you possibly can. This is just demonstrating the reduction in the down border. Roughly a reduction of about a half a millimeter. Now we're in the consumer space. This is a 13.3 inch. It's a 2.8K fast frame rate, 120 Hertz touch embedded display. So it's not an add on PCAP sensor. It's actually embedded in the TFT cell itself. A tablet would be a typical application. So it's not capacitive. It's PCAP. It is PCAP. Yeah, protected capacitive. But it's in cell, not on cell. So it makes it thinner. This is a very fast frame rate demonstration. Very high frame rate, 480 Hertz. So typically liquid crystal displays refresh at a 60 Hertz rate. This is 480 Hertz. And again, we're in a consumer space. This is a 16 inch. It's high resolution 3K by 2K. It uses a mini LED back plane for high dynamic contrast. And it has 2000 dimming zones in the back. This is a 1.5 inch flexible AM OLED display on a flexible substrate. And that would be used for complex shapes. This is a free form. It's round. Nice. Yeah. All right. So what are we checking next? Well, why don't we go over to the medical diagnostic monitors. All right. So with these two displays, TIEMA has always been very involved in the medical space. Especially for medical diagnostic imaging. The display you're looking at right here is a 30.9 inch 12 meg color display. And in reference to that, I want to show the panel to the right, which is a 21.35 meg color. Now we're only showing black and white here, but it is a true color display. This is normally used. This is a standard in the medical imaging X-ray diagnostic field. But if you notice this particular size, which is a standard, typically you would have a radiologist that would have two of these side by side. The problem is, is because there's two different panels side by side, is they could be slightly different in color temperature, in color reproduction. And that's very critical in imaging like this. Therefore, if you follow this and you take this over, you will notice that this single panel is actually two of the displays. Now what that does is that it makes sure that the color performance from two AB comparison displays is equal. This is also a 10-bit driver, so color resolution is very, very finite. And it uses a photo alignment to make sure that black levels and uniformity across the entire surface are very uniform. When you have the perfect solution there, then you have three or four million doctors in the world, physicians, what's called surgeons, they'll want to have it. Yeah, I mean, I think the whole X-ray imaging world is transitioned from film-based to digital-based for lots of reasons. Storage capacity would be one. The next is another one of our strengths, which is applications in the marine market. This particular display is a 20.8 inch. It's a 4K by 2K in resolution. It's a very, very bright display at 1400 nits. So in the marine environment, it's very important to select the materials that you use. So we use outer polarizers and liquid crystal material that can withstand high UV exposure. Because typical, if you use just standard polarizers, they would weather, they would yellow over time. So this particular display is ruggedized for the marine environment. Next display is, we call this our invisible technology. And we're developing, this is a film-based pattern on the outside. We're developing these four films, silver all the way up to red oak. And really what it allows it to do, this is more for aesthetics of design. So if you can turn off the display, the display disappears. So there could be some aesthetic designs that you don't want to see that there's a display available until you actually want to use it. So you can see here, it disappears, but yet, there's still a touch function. Nice. It makes it attractive for people to go and touch and play with devices and smart home controls and everything. It's an aesthetic design, consideration. And they are thinking about that in the automotive space, which we'll get to in a bit. Another one of our strengths is in the industrial space is high-shock and vibe displays. This particular free-form display, circular display, is capable of withstanding 10 Gs of shock, which is very, very high-shock. That can be used in things like tractors, earth movers, any place where you have real high-shock and vibration environment. The next three displays are, again, we're in the industrial space. These are typically more custom-made products. Each one of them has what we call our TED technology, which is touch-embedded display. That means the PCAP sensor itself, the touch sensor itself, is embedded in the TFT cell. It allows it to be very, very thin. Same is true here. And a little bit larger inside, same is true here. This is our latest generation of wet and glove technology. And those that are familiar with PCAP sensing know that for outdoor use where there's exposure to water, false touch becomes an issue. This is demonstrating that the touch functions are working properly, even with water dropping on it. You see how we mentor lots of water drops on here, that everything is functioning correctly. Works with gloves, too. This just demonstrates our ability for PCAP integration. This is a very large 27-inch full HD display. It has an external PCAP sensor, as you can see here. So Tianmue is capable of doing a 30-inch PCAP sensor on a very large display, up to 30-inch. And soon we'll be able to go to 32-inch. We also do the custom cover glass, you see there. All of this is direct bonded at our factory, OCR-bonding, wet bonding. That's good. Big touch screens? We are doing a lot of touch screens. Not quite that large yet, but again, we're showing that we have the ability to do that. It just depends upon the customer demand. So the next three displays that we'll be looking at here is, as our company has progressed, we had two product ranges. We had what we call our TM product range and our NL product range. Now we're standardizing on our product range. It's called our P-Series product range. And displays in that product range will be available in three different flavors, if you want to call it that. One is entry, the next is basic, and followed by advanced. So what you get as you step up in range is you get higher brightness, more rugged, more contrast, more backlight life, things like that. The other thing that we've done is we decided to standardize on wide viewing angle technologies. It's our SFT technology, and that will be throughout the range. Leveraging off of our production technologies is the possibility of moving into different product ranges. The first one that you're viewing right now is called a microfluidic chip. And in essence, what it allows is rather than a human picking up a sample, a liquid sample, and moving it from location to location, you place it on the surface, and by computer control can move that fluid sample. So basically what it aids in is an automated way to move a fluid sample from test station to test station. So for higher throughput. This is a glass-based chip technology, chip bonding technology. So as you can see here, it starts with a substrate with a chip. This is actually a CMOS sensor. It is separated. It's moved to a circuit board, and finally to a camera module. So it's a CMOS camera module. This is a phased array liquid crystal antenna. And this would be typically used for reception of a commercial satellite. It's not for home use. It's not for consumer use. Starlink? Starlink would be a perfect example. Does that mean you're using the LCD factory to make an antenna? Yes, absolutely. I mean, these are the things, you know, we're just leveraging off of what we already have in-house. And looking to expand. We're now moving into the automotive space. And this is an 11.6 inch. It's called camera under display. So what we've done is we've integrated an infrared camera in the lower part of the display. Yeah. So part of a very hot topic these days is driver distraction. So the idea with this particular technology display is it will auto-recognize. You see how it recognizes my face right now? Now, let's take it one step further. Let me take my cell phone out. You see how it recognizes the phone? And now it's giving me a warning. Nice. Don't use your phone while driving. So it's a biofeedback for safety purposes in the automotive world. And it can be many other things. That's just for a technology generation. You have a big presence in automotive? Yes, actually it's a really, really hot area for us right now. We're one of the top suppliers to the automotive world. All of the world? Yes. For every continent of car makers. And there's so many innovation happening with the electric cars. Yes. And you have to supply what they want for two, three years in the future. Yes. And again, this whole automotive space is really an exploding area for us that we've jumped near the top. This is a haptic feedback. You see here when I touch it? It gives both optical and physical feedback. That's just feather touch. And then you can vary the strength of the feedback itself. And you got the people's choice award. That's correct. That's correct. So the display that I showed earlier is based off the same technology. So we call it invisible display. In this particular case, it's a curved display. And let me show you here. So the idea again is I think all of the interior designers for automobiles are looking for that next design element. And part of that is making the active displays go away and making more of a cosmetic attraction. What we've added in this particular technology display is a privacy filter on the right hand side. So as I said earlier, driver distraction I think will be a key point going forward. You can change it on and off. Yes. If you look from this side, as if you were a driver, I can change the privacy of just this part. You have to look at it from an off angle. This angle. All right. Nice. Okay. Yeah. Nice. Yeah. So that one, the people's choice of awards. Very nice. Very nice. It could be automatic when the car drives. Could be. Yeah. I mean there's many ways to implement it. That's just one. This is a 17.3 inch. It's a LTPS display also with touch embedded. It's the PCAP sensor is embedded in the TFT cell itself. Very high contrast ratio of 1500 to 1, 10 point touch. High color gamut of 80%. Yeah. Next display is what we call our 15.46. It's an LTPS display, but it's T-shaped. And typically the way you would do that is you would combine two different displays. One here and one here with just a common cover glass. In this particular case it's one display. It also has touch embedded in it and very thin frame perimeters. So we're thinking in terms of free form shapes for new interior design. And you have a few years of experience doing free form. Oh yes. We've been doing it actually for quite a few years now. We've got circular many different shapes. The next is a 15.6 inch. It's very high resolution 4K by 2K. 3840 by 2160. Also very high contrast ratio of 1200 to 1. That could be the main display in a self-driving car or one of these electric cars. Could be. I mean it's very high resolution and they're kind of debating right now. How much resolution do you need? I mean for maybe passenger entertainment when you're looking at a movie or something like that, you would prefer that type of resolution. Driver doesn't necessarily need that. If I can choose an Uber with a 4K display in a backseat, I'll choose that option. Yes, of course. It would be fun to see. This is a 9.94 and it's a multi-fold OLED display. And so we're trying to bring OLED into the automotive market. There have been challenges with temperature, but we believe we can bring OLED into the automotive market. This is a 12.3 inch. It's called Accurus, which is an advanced contrast ratio. It's a dual cell display. So there are two cells that are bonded together. One as color content, the other is just basically a gray scale. And by doing that, by varying the gray scale portion of that, you can get high contrast ratio. That's really what you're trying to achieve. This is a different way of achieving something that's very high contrast ratio and very much the buzzword these days. It is an active matrix mini LED backplane. But this particular one is chip on glass driver. It is mini LED on glass substrate and LTP as glass substrate. The advantage of that is you can reduce the driver count as opposed to the other way of doing it, which is on a circuit board, which requires more drivers, up to like 10 drivers to do that. So very dynamic display. Right. Nice. Yeah, we could show this also. We'll have to come in here. Right. At display week, I've never experienced it before. Yes, it needs to be. So what this combines is it combines not only a privacy filter, but it provides the front surface of the display or the display itself vibrates a pretty sound. And it's very, very directional. So again, driver distraction. If you would want to create a sound field that's very, very directional, so only the passenger can hear it and the driver is not distracted. Is it active now? You can... Yes, you have to stand about right here. All right. Listen carefully. There. All right, I hear. Yeah, I just need to position myself exactly in the right place. Yes, it's very directional, as I said. Nice. So that's for the Uber driver who loves music and the passengers once quiet. Yeah. All right. So it's been a great show. Thank you. I'm glad you came by. And lots of people, it's back to normal, right? As normal as it can be, yes. And here at the front, there was this one. Yeah, it's another automotive demonstration. I think we can come in this way here. So as many people have already experienced, very wide format displays are becoming very common in the automotive world. This was an example of an aesthetic design that appears to be all wood and it makes the display disappear. But if you touch it, you see now the display comes alive. All right. Your car is saying hello. Nice. Yeah. That's awesome. You can see the information on it now. All right. Thanks a lot for showing everything at your booth. Glad you came by. Check out the WISE. WISE is such a smart system. I think I'm saving over a thousand euros every year because I use it everywhere when I pay for stuff. 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