 No, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no. All right, we have some revisions first. Yeah. This is like a two year old revision by fine. Got it done. The 096, 160 by 80 color TFT breakout. So much stuff, one out of stock was unavailable, got revised, and it was just like a bit of a chase. But we finally got all the parts to be able to revise it. So this board is very cute. It's basically our smallest TFT. It's less than one inch diagonal, 160 by 80 pixels. It's IPS. It's a beautiful display. And then like stop here because I'll show what can go back to that. Yeah. So let's explain what changed. So the TFT actually wasn't unavailable. We couldn't get the TFT anymore. And so we decided if we're going to redo it, we might as well update to a plugin TFT, which makes manufacturing so much easier because you don't have to solder the TFT anymore. So to do that one, you'll see on the back, there's this little plug that goes through the back and then plugs in the pin out and shape and size of the breakout is the same. The TFT is the same, you know, resolution, but the initialization code is slightly different. Basically, it's inverted or it's not inverted compared to the previous one. So we do have updates that we're going to have for the code so you can select which version of this display. If you run the display and you're like, hey, it's just inverted, like the colors are backwards, like white is black, black is white, red is green, et cetera. That's why. And then it should look like that. And then the other thing is the SD card we're using now in Molex. It's a very nice micro SD card slot, but it's push pull dot push push because there's no, there's not enough space for their standard push push, which means that you don't push in to pop the SD card out. You just pull it out. So otherwise, it's, you know, basically exactly pin compatible, almost exactly code compatible. I'm just glad that we finally got this back in stock. And when we have new product photos, we put some of these amazing new quarters, the American women's series from the US Mint. Yeah. Other revision. Okay, so that's the, that's the still the culture. Yeah. So the second revision is this color OLED, the 1.27 inch color OLED, which is one of our older products now got revised. First off, it's got the next new Penguin font. It's a black PCB and we've updated to have an iSpy connector on the back. So this is our plug and play way of getting connections going. Let me just get a demo. You're getting a demo. You get a demo. Yeah. So it's otherwise pin compatible, code compatible. Yes. So why don't we go to the overhead. So for example, I've got my little Q-Spy board and a little prototype iSpy connector. And then I just use this flex cable to connect. So it's much easier to connect displays. So as we're revising and updating many of our displays, we're adding when we can. These 18 pin FPC connectors, because it just makes for really easy connection. And yeah, like Philby, we did the graphics demo. So nice font colors, graphs, et cetera. So otherwise it's exactly the same, you know, if you were using this display before, you'll notice, you know, other than the PCB color and font. It's the, you know, identical, the SD cards in the same slot and everything. But we had, we just shoved everything over a little bit to make room for a flex connector. So this is the latest in the iSpyfication. Okay. Oh, and yeah. Yeah. So this is my entry. Yes. Okay. Next up. Next up. This is coming soon, but I figure I put it in the shop because I think people are excited about it. It's a little board that you can plug into the back of your QT pie that gives you a micro SD card. So this is that same micro SD card slot we talked about earlier. Very handy. If you want to add more data storage, you want to do data logging to an SD card. I just love those. Yeah, those micro SD card slots are just so darn cute. And so they fit perfectly on the back. And in this case, we put sockets in and we just plug it in, but you don't have to. You can solder it directly to the back and then use the SPI pins. And one chip select pin. And then if you go here, you can see the chip select. You can, by default, use the TX pin because I don't want to use the analog pins because usually you're data logging from analog or you want to use those for something else. But you can cut that trace and select RxA0A1 and then that little square jump, you know, a little dot at the right hand side. That's the CS pin. So you can always jumper that to some other pin if necessary. All right. Next up. Okay. So we put in a bunch of RP2040 chips. And if you're going to use those RP2040 chips in a design, you probably want some flash memory. And so this is our favorite flash memory. And I like that they put it on top of her hand there. Yeah. This is the Wynbond W25Q64JVXGIQ, which is a QSPI enabled. It also can do regular SPI or dual SPI if necessary. 64 megabits, 8 megabyte chip. It comes in a, I think this is called a WSON or an Exon. I think it's Exon size. It's basically hand solderable. It's a little bit smaller than SOIC, but it's got the same kind of size and shape. And it's, you know, a great, it's a very inexpensive 8 megabyte, 64 megabit flash. We love 8 megabyte. I think it's like enough space that you can have a little storage for files, fonts, images, audio clips. You love it. And still have, what did you say? You can do a lot. You can do a lot. I think I said you love it. I'm like, yeah, you can have you law files. Yeah. And also. Yeah, that too. Yeah, I love these law files. And then it goes great with the Raspberry Pi RP2040. So we have it in sets of 10 and sets of 100 to match the 10 and 100 RP2040 chips. Next up. Okay. Next up, we're going to get some more products from other vendors. Just been out. I've been out for a couple of months, but we're back. And so I'm getting back to stocking some cool stuff. So we're doing some experimentations with HDMI DVI output on the RP2040. And I thought, well, let's carry this cool dev board from Pimeroni. This is the Pico DV. You don't have to be confused with HDMI because HDMI requires a licensing agreement. This is DVI, which is a free and well documented protocol that you can plug into displays that have HDMI written on them. Works great for that. The Pico RP2040, if you overclock it and you run some kind of like tweaky code that is a lot of PIOs, can output DVI signals. And we've done it. We have some demo code we're going to release as well that uses it. And we're prototyping on this board. This also has a micro SD slot. It has three buttons. It's got some GPIO. I think the SD card looks like you can do SDIO as well as SPI. And it's got, you know, like an able jumper maybe. It's got a couple of things going on there. If you wanted to do some AV hacking with the RP2040, you just plug your Pico in. No song required to use this if you use a Pico with headers pre-attached. Next up. Next up, we've also got the same version of that, basically the same as that board. But this one's got a VGA connector. And look at how skinny that VGA connector is. That's like the skinniest VGA connector on the planet. That really, that's kind of scary. Same thing, you want to hack your displays, but it's an older display. Maybe it doesn't have DVI or HDMI written on it. It has VGA written on it. Congratulations. You can use this instead. Video graphics array. Yeah. I mean, it's still doing the same thing where you get, you don't get as many colors. I don't think because you, I think it does like averaging between two or three pixels. So you get like maybe eight bit color. Still beautiful. It feels too black and white. Good for hacking on AV projects. Next up. Next up. We sell in the shop, various Laura boards, breakouts, feathers, et cetera. But maybe you want to go to space and send Laura signals to and from your space balloon. Then in honor of the challenger, you can pick up one of our Laura radio boards, radio modules. This is just the module. It has inside of the SX 1276. It's tuned for about 900 megahertz. You know, basically in software, you can set it to 915 or 868. It's, it's good. You're going to get totally fine signal either way. And that's the ISN band. You would use, we have in circuit Python and I think micro Python also and Arduino all have libraries for the SX 1276 chip set inside. You connect an antenna to the antenna pin, connect power and all the signals to the other pins. And you basically have a Laura transceiver. Now it's a little tougher to use than our module that has level shifting power supply antenna connector. But you're designing your own board. These are hand solderable. So we put them in the shop so people can design their own boards. Next up. Next up. It's kind of seen but it's coming seen part two because last time it was coming soon. There was a chip shortage. We couldn't get to the chips necessary to build this board, but now we can. And so we're starting to revive this. We just want to kind of bubble this up in people's consciousness. The Metro M seven featuring the IMX RT 10 11. It's a 500 megahertz beast Cortex M seven. Yeah. It's a bit of a beast. Although I want to, it doesn't have a ton of pins. Like you'd think, oh, this should be so many GPIO. It's actually exactly this many just enough to do a metro because a lot of those pins are for power. Or for, you know, SWD debugging. But we also hooked up an ESP 32 on the left there as a wifi coprocessor. It's got stomach UT SWD debugging and nine volt the nine to 12 volt DC input reset button. There is a built-in ROM boot loader that you can get into by switching those jumpers on the switches on the boot select. Basically, we got these, we got, we updated the flash to be that eight megabytes of Q spy. Because again, we, we like eight megabytes. We're basically going to be, you know, getting this to our developers. We went to kind of resuscitate the efforts that we put in two years ago. We did have circuit Python running on this board quite well. And we just again couldn't get the chip anymore. And so we shelled it. But I think we're going to start getting into Cortex M seven now that you're available. They're very exciting chipset. After this, we can follow up with other IMX chips as well. But we're starting with the low cost IMX RT 10 11. Next up. Next up. It's now in stock is the OV 56 40 camera module with 120 degree wide angle lens. We chatted about this earlier. It's, you know, a nice upgrade to the standard OV 56 40 camera. Or 26 40 camera. This is a, you know, very nice quality camera with a wide angle lens. There's a couple updates that I did to the design to make it, in my opinion, a lot better than the standard camera breakouts. It has that two by nine header that every camera has. It's got a jumper for the V motor pin. If you have an autofocus camera module, this one doesn't autofocus, but you could swap in or we might release later version autofocus. We have pull-ups on the I squared C lines. We've got a, you know, a small light green LED to tell you that it's powered on. You've got optional internal clock generation for 24 megahertz clock. If you don't want to spare a GPIO pin to do it, it's got, you know, pull up and pull down on enable and power down as necessary. So it kind of boots up immediately. It's got a little heat sinking area up top. Some of the camera modules we've noticed can get a little toasty. So giving it that exposed gold area, you know, you can attach a tiny heat sink if you need even more heat sinking on, on that module. And I thought I'd show a little demo of this board. So the only thing I want to note is that this board is, this board, it does have, you know, this two by nine connector. And we added, you know, in this case, I soldered both pins on, but we added another row. So you could plug this, you know, if you didn't solder in the second row, like I did, like if you had it like this, you could plug it into a breadboard. And because, you know, it's very hard to plug in dual row, because you have to have like some sort of like divider thingy that brings the pins apart. But it's meant to go on boards like this Kaluga, which is an ESP32 dev kit. Here, let me bring this a little bit. This dev kit, which has a camera connector and a lot of dev boards, if they have one of these two by nine connectors, it's meant for camera. So I plug it in and then we see power. Let me see if this boots up and get my live demo going. You can do it live demo. Okay. So this is the circuit Python code, which grabs a camera frame. And you can see I'm waving in front of the camera. Hello. This is us. This is the bassinet. So this, this camera module, you know, it's a nice wide angle. You can see it kind of distorts on the side just because it's doing that wide angle distortion to get the full frame. And it's a little rounded at the tops with the corners of the room. But this is the, you know, circuit Python code, just displaying it on 320 by 240. And then of course you can download. It auto-creates JPEGs, if desired. We have code to do that to capture a JPEG image. You could make your own digital camera. You could make your own digital camera. So we're going to start with the OB-5640, where people will also have versions with different lenses, autofocus, 2640. But this is the, you know, this is the camera lens. I kind of like the most. It's a great starter lens. And I wanted to get, you know, this, this breakout, which again is the standard breakout for cameras, well-established. Hi. I think, yeah. Okay. Start the show besides you, lady, our entire team and... Oh, I'm having a blank screen here. Hi. It's the void. It's the floppy feather wing. It's here. It's here finally. Yes. Again, we're getting to... What? That's the... Man, I keep, I keep... No, because you clicked it off the ground. Okay. So anyways, the starter show besides you, lady, our community, our customers, and everyone else. Yay. Yeah, this is... Yeah, this show is huge. There's a lot going on here. You can't, you can't... You can't watch this show because it's so weird. Yeah. You can tell it's live. Okay. Floppy feather wing. So we're going to do more floppy stuff, but we want to start with the floppy feather wing just to get some, you know, basically the wiring of floppy drives is the toughest. So floppy drives, PC floppy drives are not Apple floppy drive through support. These are also not, you know, Commodore 64. This is for standard PC, classic PC 3.5, 5.25 inch floppy drives. They use this 34-pin IDC cable, two by 17 pins. One row is ground, but the other row is like all the GPIO that are used to communicate with the floppy drive. And floppy drives are very, very low level. So you do need to have... First up, they have to be 5 volts signal because the floppy disk is really expecting 5 volts signal. So on the floppy feather wing is level shifters to and from the data. So all of it is converted to and from 5 volts to 3.3 volts. And then... Oh, let's show the back because it has the pins. So there's a lot of GPIO used for floppy. So you see from the bottom, index, step, direction, enable, de-enable, I don't remember what de-enable is, select, motor select, and then above right data, right gate, protect, track zero, read, side, and channel. And I think I'm hoping I'm getting all those right. There's a lot of signals on the floppy drives. So they all go to individual pins on the floppy, is on the floppy feather wing, and then are level shifted into the feather. So the thing about the feather is data that comes from the floppy streams out very, very quickly, and you can't really just use any chip you want. You really want something with a lot of RAM and very fast GPIO, especially something that has like a DMA GPIO that you can stream that the data transitions that just like pour out of the floppy drive into RAM. And so for that, the best use case in our opinion is to use an RP2040. You can also use a feather M4, although right now it's hard to get to Sanbi 51 chips. So honestly, what kind of saying just go with the RP2040. You'll need to pair that with this and then run the software that we have written. So maybe if you go back to us because I have to explain a couple more things. Okay. So there's three use cases for the floppy feather wing. One, you want to archive floppy disks and save them for like later perusal. Maybe because, you know, you have this from your childhood or you're archiving, you know, historical documents or whatever. You have the prints floppy. You want to get the data off. So you would use the floppy feather wing with the RP2040 and use our firmware and this desktop software called Grease Weasel or Flux Engine to read those raw fluxes off and then you could do data correction if necessary, like bit error correction and then convert that image into, you know, whatever format it is or the IBM PC or even Mac. You can do some Mac formats as well. The second option is we also have code for Arduino and CircuitPython where you can treat it as a file system. You can like read the files off. You can even do some writing, although the writing is kind of iffy. That's tougher to do. But the reading, you can read data off of the floppy and kind of treat it just like a normal file system as if it was an SD card. So that's good for like retro projects where you want to like use the floppy as, you know, an interface to actually store data on because it's like cool and retro. And then the third option is you want to make like weird music and you want to control the floppy disk and you want to like make the motor go back and forth and like click and there's a lot of videos which I linked to. So there's like the three main use cases for the floppy feather wing. But it's still, I gotta say you have to get a floppy disk and they're not new, right? They're no longer made. The floppy drives are no longer made and you have to power the floppy drive separately and those will require like five volts or five volts and 12 volts multiple amps. So you may need like an XC power supply. So this is not like a super beginner board. Like you have to get a couple of things going. Try to make it easier. But the fact that you can't buy off the shelf floppy drives anymore to make it a little bit more complicated than other products where, you know, everything is available in the store. Okay. That's new product.