 new lot of screens if i screen new screen we all screen for screen screen okay this is the 3.4 inch. uh squared 480 by 480 display without touch screen. um. let's go to the overhead. i can show my demo. I finally got all these demos going. So this is what he's looked fantastic in person. And we're going to still show them on all the overheads. Yeah. So but we know we do our best. Okay. Screen through screen through screen screen. So this is the version without a touchscreen. So you see it's much thinner and it doesn't have a bezel. And this is a version with touchscreen. So it's kind of tough to see this on. But it's got the glass bezel. So it's got more protection. It's a little bit more expensive. And here I'm driving it with the Qualia ESP 32 S3. You do need a micro controller that can or a micro computer that can drive these RGB dot clock TTL displays and most can't USB 32 S3 is kind of unique in that ability. I have here just doing a color demo and then this is also a touchscreen. So you see as I touch it with capacitive type. So I touch it with my finger. I'm drawing little dots. So this is a 480 by 480 square 3.4 inch diagonal display. So it's the first of our set in capacitive and noncapacitive. Next up bar display. Two TFTs walk into a bar. So this is a 3.2 inch 320 by 820 I think bar display also available both with and without capacitive touches is without. And then if you keep going without the capacitive touch, you see it's much thinner and then yeah, that one with the bezel with capacitive touch. So this is the other one that has that's that's the last one. Yeah, back to the yeah. So there's differences when that's a 4 inch. They look slightly different. Okay, so this is the 3.2. So this is the bar display. So it's much more rectangular than most. But it can be really cool. So I think there's a lot of times where you like you want a very slim display with a lot of pixels or 320 by 820 pixels. Let's go to the overhead and I'll show this one next. So this is the two versions. This is without the touchscreen overlay. You see there's no circuit here. This is with so it's got that nice glass bezel. You're going to pay more for capacitive touch. But the without capacitive touch is also perfectly fine. And this demo is also showing off this one. You need to be a little closer. Yeah, so showing off it looks, you know, amazing in person, but it's a TFT of a TFT of a TFT. So this is also capacitive touch. So you see I can touch it with my hands and the white dots show up over the rainbow. So using a quality ESP32 S3 board for this, again, you do need to have a microcontroller that is designed to work with RGB dot clock TATL displays. You can do like 16 bit color and large displays. But we've got example codes and a tutorial for this in Arduino and circuit Python. And then finally on the display train is the four inch 720 by 720. So this is definitely like as big as it's going to get for a number of pixels on these displays. We also have these in with and without capacitive overlay. So this version, you know, happens to be the photo we added is the one without capacitive overlay. But the demo I have on the overhead is with so we can go again to the overhead. Again, driving it with Aqualia ESP32 S3, which is designed to drive these displays. It's flickering because it's you know, it's a camera taking a photo of a TFT. But this one is also a touchscreen with capacitive overlay. Capacitive overlay is going to cost a little bit more. But of course, it has touch and you know, it's got a nicer look because there's a bezel to it. So you decide whether you want with or without capacitive touch bezel, and again, supported both in Arduino and circuit Python. All right, next up. Okay, this is our vision. We have our can feather back in stock. It is the SAMU 51 based can board now comes with the terminal block pre attached might be in green might be in blue might be in black, but even less soldering than ever, it's kind of plug and play ready to go. So you get you know, a samd 51 that has a can peripheral built in. We toss on a transceiver terminal block. Are you ready to do can communication on a Cortex M4 in Arduino or circuit Python? Okay, so we now have the USBC C version of this kind of like built in monitor cable. So this version has USB C on one side, USB C on the other side. And so it's good for if you want to use this with USB PD power delivery, it'll tell you the wattage that it got on the other side, which is handy, because otherwise, you know, there's no real way to know like, did the power delivery work? Am I getting that, you know, 100 watts or 50 watts? Because by default, five volts one amp is only five watts. So if you see like this image, you can see, you know, to get 11 watts, the power delivery must have worked because you're not going to get more than 10, unless you have a functional power delivery. So phones, tablets, you know, computers like Raspberry Pi, whatever. Other devices that have power delivery laptops. This will be a very handy cable. It's a very nice quality. And also like, you can now tell what is the fastest charger in the house. I use all the time for when I'm charging, you know, my laptop or my tablet, because you know, sometimes some of the PD power supplies I have, don't have the exact voltages that the device wants. This way, I don't have to like look at the little text and unplug it. I just plug into one after the other until I'm like, Oh, that's the one that gives me 30 watts. Great, I'm done. And so tonight, I said you lay data our team, our customers, our community is. Yay, it's the the zombification of our 2.4 inch TFT featherwing. This has been like two years out of stock because TFT shortages, chip shortages, but it's now back. It's better than ever. So glad to see this. We did the TFT shield. Sometimes it takes a long time to do these big revisions, but I think it's worth it. So if we stop on this image, the big changes are we now use the TSC 2007, I squared C resistive touch controller instead of the STMPE SPI touch controller. So that's kind of nice. So now we have one free pin. We used to use it as a chip select, but now we're using I squared C. So we don't have to have another GPIO pin used. So we connected it to the IRQ line. So if you want like really fast notifications of touch input alerts, you can just watch that GPIO using interrupt. We updated the silkscreen. It looks really nice now using Futura. The reset button is right angle now. And we also added a STEM IQT port. You can see that kind of the bottom right area. And I can just I can show the demo. I mean, the demo is very similar. Yeah. Why not? All right. We'll get in. Okay, so over head. So this can work with basically any feather. I've tested it with the 32U4 up to RP2040 and the SAMU51. So anything that uses SPI and I squared C in the correct locations will work. You can read images and files off of the microSD card. You can use the on off to turn on off. So like, you know, I want to quickly turn off the whole thing. That's kind of nice. This is the reset switch. It's now right angle. You can see it starts over the program, except my SD card doesn't like it when you cut power in the middle. So this is a demo which draws some flowers off of the SD card. And then there's a resistive touch screen. So resistive makes it inexpensive, but you will have to use something kind of pointy. You can't use your finger pad unless you really press down. Fingernails work best. And then the STEM IQT port is over here for boards that don't have it like RP2040 does. And then if you want to connect to the backlight to control by default, that's always on or the card detect that's also available. But I know people have been waiting for this redesign for a long time. And I'm kind of psyched that man, I mean, SD card, this SD card really likes to be power circled. I'm glad to have it back in stock. It's back. Yeah, some images and more and just another example of we don't give up. Dude, dude, I did so many redesigns.