 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, this week, first up. Okay. First up, we've got this little adapter. This is for the Quick 861. It's a very, very nice hot air system that we've got. Only thing that's a little annoying is it uses hot air tips that are not compatible with the low-cost ones. This little adapter, it's a couple bucks, and you put it onto the 861 hot air gun, and it lets you use the low-cost hot air tips. We carry a pack of 10 that has, like, QFN and, like, 100 QFP pins and all, like, everything makes it easy to do large packages. So you don't have just, like, the round nubs on the end of your hot air station. Okay. Next up. Next up, we've got some chalk breakouts. So we have done lots of keyboard projects, and if you have used any of our keyboard breakouts or macropads, whatever, you know that we tend to use the MX Cherry MX-compatible switches and sockets. But some people want something thinner, so if we go to the overhead, I'll show the difference. Yeah, I'll show you something else. So this is, yeah, go to, well, we'll get back to them. Okay, so this is the, I'll get this out of the way, but I love did you keep it, it's a little confusing to see it. So this is, like, you know, our feather wing with NeoKey, and it's got two MX switches, and you see they're quite tall. There's two different keycaps. This one's kind of like the shortest keycap you can get, and this is kind of a standard keycap. But it's very tall. A lot of people want something nice and short, so this is the chalk by comparison. So it's like, you know, definitely more than less than half the height of the MX. It's a very, very slim style, and the keycaps are very slim. So if you want like a low, you know, laptop keyboard like key height, the chalk switches are where it's at. They're totally incompatible in every way from the MX, which is the keycaps. You can't use MX with chalk or chalk with MX. The keys are totally different. You can't use them in different sockets. So this is a completely separate breakout, just for chalk switches, and I'll show, even on the bottom, the socket is totally different than the socket that we use for MX switches. You can see the two sockets here. But, you know, so we made a little breakout, you know, to account for all the differences so you can quickly breadboard chalk projects. Another thing, just to note, compared to the MX breakout, these breakouts are one well taller. So they're 0.1 inch taller longer because of the way that the socket fit for having the socket fit on the PCB because it has to fit a little bit higher. I had to extend the circuit board. So just FYI, it's even though it looks just like the NeoKey for the MX, it's like a totally different configuration and a totally different pinout. The pinout's the same, but totally different PCB size. So let's go back to the photos. Okay, so that's the demo. You're going to connect as many of them as you want. They come with diodes built in. So if you would like to have an array of them, go to town. They're diode connected. There's also a little reverse mount NeoPixel. A socket, we stock both the clicky and linear chalk switches, but of course you can use any chalk compatible. NeoPixel shines through and then breakouts on the left and right that connect the NeoPixel input output, the NeoPixel power and ground, and then the switch anode and cathode. It goes through a diode. So that's why it's labeled anode and cathode. Okay, and then the stars show tonight. So do you lead our team or our customers or community is? Okay, with the ANO rotary. So that's the name of the rotary encoder. It's the part number is called ANO. So that's why it's called ANO. The rotary encoder with seesaw. So this is, you know, we've had this encoder for a bit. I love it because it's basically iPod classic rotary encoder where you've got the little click wheel in the center. It's a rotary encoder and then up, down, left, right, and select. But the thing that's a little annoying about it is there's five buttons and two encoder pins and it's a lot of pins. And before you know what you're like, I've just used half of my microcontroller GPIO. And, you know, you're constantly pulling the encoder. And so why not make it a lot easier for people by making a breakout board where on the back is an AT tiny 816, the little AVR chip. And, you know, the code is up on GitHub. If you'd like to take a look at how it does this, it can keep track of the encoder. So it just keeps a little counter of how many clicks left or right. It can read the buttons and it can also have four different address select switches. We can directly have 16 of these all over I squared C, three or five volts. So it's very easy for you to connect this up to your Raspberry Pi, which doesn't even have rotary encoder support or other single board computer. You can connect it up to an Arduino. You can connect up to a Pico. You can connect it up to pretty much any microcontroller as many as you like. You can even connect it to a computer by going through one of our dev boards or one of our USB to GPIO converters that once took your Python and on board is a little seesaw chip. And there is an IRQ output if you'd like, but it also works just great over I squared C as long as you don't mind asking it every once in a while. Hey, are there any buttons pressed or any rotary encoder clicks going on? And that's it. That's the product I can, you can show the little demo video. So this is just the hand and you can see it's plugged into a seven-segment display. And then, you know, it just counts up and down as you click the little encoder. That's your products.