 No, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no, no. First up. This is the AGS02MA sensor. It's a, it looks a lot like those like DHT11 or 22 sensors and it's actually made by the same company, which is why it looks the same. So the AGS02MA has a mox gas sensor inside and a little microcontroller chip that acts as an I-squared C peripheral. Basically means that you can use this as a low-cost and simple TVOC total volatile organic compound sensor, gas sensor, you know, for ethanol, methane and similar gases. It can detect those in the air. It basically does a simple calculation to do parts per billion. You can also read the gas resistance is only one gas resistance plate. It's, you know, not super calibrated, but it's very inexpensive and, you know, plug and play works with three to five volts. One thing I will note about this sensor is it needs to run at under 30 kilohertz clock for I-squared C, which is unusual because the default I-squared C clock for many boards is 100 or 400 kilohertz. So you have to tune your I-squared C controller to run. I use, you know, 20 kilohertz, for example. Some controller chips like the RP2040 and ESP32 were happy to do this. I told them, hey, please run at 20 kilohertz and they're like, sounds great. So did the, at Mega328. But there are other chips, the SAMV series that was not very happy about running at that low speed. And so just be aware that you have to make sure that, you know, maybe check on a oscilloscope that you can run your I-squared C controller at 20 kilohertz before you pick up the sensor. Other than that, it works pretty well. We have a new camera lens for the M12 camera from Raspberry Pi. This really nice lens mount on the camera allows you to plug in screw in different lenses. We go like wide and we've got, I think, a narrow telephoto and this is a portraiture one. So this one has a narrow field of view and also I think a narrow focal range. And so you, you know, it'll focus nicely on a face and get like the depth of the face. But it'll kind of a blurry background for that cool modern portraiture look. Yeah. All right, next up, this is what we were talking about earlier. Yeah, this is the Pico debug probe kit from Raspberry Pi Foundation. So this is kind of an all-in-one, the SimSys step board for debugging RP2040, but also other chips as well. It's also, by the way, an RP2040 dev board that you can just re-program. You can load whatever code you want on there. It's got two JST SH connectors, three pen, and it comes with three sets of cables. Let's go to the overhead because I feel like this would be it. Yeah, we have a new overhead. You have a new overhead too. So let's test it out. So you can, if you move your head over, people could see you as you're doing this too. Look at that. Oh, I have two. Or not, I can get rid of that. Yeah, maybe get rid of me because I'm not ready for that yet. All right. Okay, so hold on. I want to focus. I know, I'm going to get this new, this is all new, so I'm going to go ahead and do this. Okay. So this is your classic Raspberry Pi Pico H. And it comes with this connector at the end. And earlier Raspberry Pi Pico boards came with three pins at the bottom instead. I'm showing this because it's convenient. You can show that this plugs in nice and smoothly. This is the cable that comes with the Pico probe. And then, you know, you plug this into, this is you for your and D for the bug. And you can plug this in here nicely. And now you still have to separately power these two. But then you, this shows up as an open OCD device that you can then use to run GDB for debugging with step debugging where you actually go through line by line. You could observe variables. You can have it break and it enters a function leaves a function when a variable gets changed when memory is attached, whatever it's very, very powerful. And if you like to do, sorry, if you have the old are Raspberry Pi RP 2040 boards, you can use this cable that has the plug headers or this version that has the socket headers. So those are two options. And then there's also a USB to serial converter as well built in. So this other port, the one labeled you gives you ground arcs and TX that you can use to read and write your data for printf debugging. And of course, you are here, but sometimes, especially when you're doing like USB host stuff or USB debugging, you don't want to use the printf debugging on here. You want to use printf over a hardware serial pin, like one of these in which case, you can use the USB serial converter and one of these plug them in. And you can do both GDB printing, sorry, GDB step debugging and printf your debugging as well. Okay. Next up. Clear knobs. Yeah, these are clear knobs. They've got a bunch of colors. We have a bunch of colors. So clear is made out of a different material. So it's more expensive. I do want to show that on this side of these, this is nice because it shows all the different angles. These are clear knobs. They are used with six millimeter D shaft or T 18. You can use either because as you see, there's a little, I think it's like a one or two millimeter. The set screw and the top has a black marking. So you can see the positioning of it. Gryff, touch amateurs or rotary coders, either one. And they're clear. They're clear knobs. Yeah. You can pick. Clear. Different colors. Yes. All right. And then the star of the show tonight besides Yulia, our team, our community, our customers, everybody who makes these go in. The ESP 32 S three reverse TFT. So many words and letters there. It's a ESP 32 S three feather. As you can see here. And so let's look at the back first. So the back is the front, the front of the back. Okay. So this is your ESP 32 S three mini module, four megabytes of flash, two megabytes of PS RAM, dual core, 240 megahertz. 10 silica processor with Wi-Fi and Bluetooth low energy does not have Bluetooth classic by the way, but it's a latest S three. And then you've got all the little accessories that you would want on that back. And I'll show you on the overhead. It's got USB C for data and power. It's got a lipo battery that charges automatically reset button. A standard QT port for I squared C to three point three vote regulators, one for the I squared C port, one for the main board. So you can have like ultra low battery usage and power max 17 048 battery monitor. So you can check your state of charge a little neopixel for neopixling. So all the GPIO you need I squared C analog input, SPI, you are, et cetera, GPIO plenty. And then on the flip side, you get a 240 by 135 pixel IPS display very tiny display with again the reset buttons also on the front because it's useful and three GPIO 01 and two connected to buttons that you can press. So you can press them to make it do stuff so I can actually show on the overhead. Okay. So on the overhead, you can see the buttons. You know, I press D one D zero D two. So we already have an ESP 32 S two. This is just the S three version. So it's actually kind of, you know, the same pin out and everything reset is handy because you can enter the boot loader. It will. So there's a U of two boot loader already programmed in for drag and drop. Of course, you can erase it. This works with Arduino and circuit Python because we have support for both of those modules. And the reason I like the reverse mount style is that you can put like a feather on top but then the TFT isn't blocked. Right. So if you want to feather when you want to add a GPS or real time clock or lower radio and then you still have the TFT on the front. Just shift this down a little bit. You still have the TFT on the front with some buttons that you can use to have it do different things. Display status, sensor output, battery warnings, et cetera. And yeah, I think it's great for IOT projects. We'll have whipper, snapper support. And again, like I said, circuit Python and Arduino all in one. I mean, you can do a lot of projects with no soldering. Just plug in the stem and QT in the back and you have buttons in a display. All right, let's do products.