Transcript of Video:
My name is Nima. I’m the CEO here at TVape, and recently, we’ve published a review of the Dr. Dabber Switch Go, and in it, there’s an error.
We referred to it as induction heating and there’s a lot of comments that came in and different people connecting through us to different types of avenues that we have as a company and they were asking us, “Okay, what is this new heater? What is it called? How does it work?” And that of course sparked my curiosity because I got wind of it and since we do have an engineering department in house because our holding company is from RYOT Systems, we also manufacture multiple brands. It was of course very interesting to me. It’s a point of curiosity and I know the guys at Dr. Dabber including the CEO Jamie. They’re great guys, very smart guys.
So naturally we’re very curious to know what is inside and how does it work. So it’s Friday here when I’m recording this and we’re already past 4:00 p.m. which in our office we have this routine. We get a bit more chillaxed here. So I thought, “Hey, let me just tear this down.” And then I thought I had this idea of like, “Why don’t we just shoot the video so everybody can see?” Obviously if you like this type of content, you can always shoot it in the comments below to tell us, “Hey, we’d really love to see more tear downs. We’d really like to know the technicals or whatever. I like to see more of Nima because I really I haven’t been front facing for the camera for a long time. So I’m going to go about it.
We’re going to open up this device. I’m going to tell you all the things I know about the different components. We know every types of let’s say component how they’re manufactured, what the challenges are, what the smart things are that our engineers in the industry do. So I’m going to break some things apart for you. So when you when you let’s say thinking about the device, you can put some color to with And yeah, as I said, uh, if you find interesting this type of comment, you can of course put it in the comments below. We can do more teardown videos if you think I should be doing them because usually other people do them, but I’m having fun today. It’s Friday.
It’s past 4:00 p.m. and usually we’re more chill. And I thought I’d just record this content for all of you guys, uh, to have something, let’s say, different with a bit more engineering inside. So, if you’re a bit of a tech freak, gadget freak, you like opening up things like your laptop, I don’t know, your uh, robot, uh, vacuum cleaner, and looking inside, fixing little things with your PlayStation, whatever it may be, and you’re curious, or you if you’re an engineer, check it out. If you have some color to add, put it in the comments below. I really would love to know, uh, what it is that you guys know that could add to the conversation, and people just love getting into the comments and just talking to each other, uh, about, uh, little things. And if you hear a little, uh, dog in the background, it’s Friday, so our, uh, office, uh, dog, Willa is there, too.
Don’t mind it. We’re not doing like super, let’s say, high quality production here. This is meant to be informative and just bear with me if I’m not being articulate or if I’m not pronouncing well, all of that stuff. Just, uh, just a regular dude trying to make a piece of content and learn something, okay? Uh, thank you very much. We’re going to go top down and you can see the details. All right.
Great. Let’s get into it. So, some of the parts of this are going to be fast forwarded. Uh, so, there’s a silicon cover here. Uh, usually peel it off. A lot of electronics have that. Kind of hide the screws away.
I’m just going to get through this uh, part of opening it. Um, and one thing I already like because I kind of checked this out, just this layer. The rest of the layers we’re going to be doing together. I noticed uh, that the secondary layer screws need a different screwdriver, which is pretty cool. Uh, I remember I had the hardest time to get into my when I was a kid, getting into my PlayStation controllers. And that was because they used these screwdrivers with like very complicated heads. So, not everyone can get into the unit very easily.
So, we’re going to get through this layer by layer to get inside this beauty. But, uh before I actually get past this level, I’m going to put the screws in a safe spot. In comparison, this is the Switch 2. Uh this is the Go. So, much smaller. And the reason it’s so big is because there’s an induction heater here. So, what do you need to create this uh magnetic field um that basically creates a back and forth current inside a metal piece that’s a suspended in it.
So, you need space and you need a lot of power. So, that’s in here. We’re not going to be doing a teardown on this one. And we’re going to go through tearing down the smaller one because that’s got the newer technology that we haven’t heard of. Uh and this is the induction heater. So, this has a titanium crucible inside. Uh I think it’s a titanium crucible, but it responds to a induction heating.
So, it heats up very uniformly. And that’s the advantage of this one. However, you can’t use that same crucible to heat. So, it’s got the same system as this one, which you’ll see in a second. And that’s basically a glass insert. Now, I’m not going to be talking too much about the air intake, which is a big let’s say important factor with these um devices working. Um and the bubblers there’s a different fluid dynamics here which make these bubblers work better or worse.
I’m not going to get into the detail of that. This one is just about the heating technology. And I’m going to touch on the side about all the different let’s say components that are on our way to get inside. So, here I’m going to take the top part off. And as you can see it, that’s the crucible that’s the glass crucible. And you see it’s super exact. That’s like something that people really love putting it in there because it’s like super exact.
And you can’t really manufacture components to be like that very easily. Titanium is a metal, so you can really machine it extremely precisely. Glass you can’t do that. So, the tolerance on glass is pretty, um, let’s say, wide. So, if you manufacture glass components, uh, and glass blowers in the audience, they’re very familiar with that. Uh, you have a high tolerance range. So, in order to make like, uh, take advantage of the unique properties of glass, uh, which everybody knows is very good for vaporization, uh, because it’s extremely pure.
You can really heat the glass up to very high temperature. There’s really no, uh, off-gas that comes from it. Um, you would love to use glass, but glass is also notoriously hard to work with. Because if you want to make a glass part that is about, let’s say, a centimeter wide, so 10 mm, and I’m sorry, I’m going to speak in meters and millimeters instead of inches. This would be, I guess, uh, less than an inch, uh, uh, it’s because I grew up in, uh, in Europe in the Middle East, so everything I know is meters, and in Canada, mostly meters as well. So, bear with me here. It’s very difficult to do it.
So, and you’ve heard Apple actually, uh, use a similar strategy for their screens, which they, uh, were telling everyone about, I think, in the iPhone 1, uh, where they matched the glass to manufacture the screen, uh, to the device in order for the ridges on the corner to be minimized. And you basically need to do that here. Because if you produce glass, let’s say, 100 of these pieces, you would probably break a bunch of these, uh, during manufacturing. So, not only do you have to throw, let’s say, I don’t know, the five out of 10 out, uh, would never get used, never see the light of day, you would also during the process of putting these holes in, you would lose a good percentage of them. So, that’s what makes these, um, actually, um, um, seem relatively expensive, but that’s because of the accuracy. It’s actually not. It’s a very highly uh, uniquely manufactured precise part and you also need a specialized manufacturer for that.
So, let’s get into the device now. And there’s also these are these have another advantage is because as it gets worn out or you see this one is obviously you see it’s already been let’s say put through some testing. Um if you want to swap it out, this is still cheaper than replacing the whole heating chamber assembly that is very common in the advanced e-rig space so premium space. So, and that’s because that those have temperature sensors in them, those have the heating element in them, those have a metal construction around it. So, all of those add up and then you get like something like a I think a Puffco Peak Pro heating chamber goes for like 120 bucks anywhere from 100 to 120 bucks. Uh Carta 2 heating chamber was also relatively high priced at like I think 80 bucks, 100 bucks. And the only other comparable would be the cheaper from the Utillian Turbo which is the heating element inside ceramic then glazed with glass.
So, this is glass. So, obviously those most of the ceramic heating chambers have glazing of glass over them. So, the last let’s say 10th of a millimeter or actually less than that. It’s about let’s say 1/20th of a millimeter would be actually glass. So, it looks like ceramic heating chamber but the material that actually touches glass part. So, these are the less upkeep cost versions of the crucible. Now, let’s get into the uh inside the device so we can see the heating chamber.
So, you can see you always can see these little foam inserts because they want to prevent rattling. And you can see inside, see how I can pull it a bit closer. You can see how nicely that’s packed. And designed for each other. Next thing is the shield that comes off. So now you have the inside of the device. Very nicely kind of put together here.
eRigs generally the battery is a very important component because you want to have a decent amount of battery capacity while at the same time you can’t make it too big because batteries are very expensive relative to other components. And also if you make the battery that needs some sort of custom sizing, these batteries need to be and I’m not sure if this is a battery off the shelf because obviously there’s a lot of battery sizes off the shelf. And it becomes very much more expensive if you custom make it and the MOQ’s, the minimum order quantities are massive. So I wouldn’t be surprised if this is off the shelf but you can clearly see that Dr. Dabber labeled the top of it and it is wrapped for them. So at least the sticker on it and such they did some customization there. You guys have get some raw view into what’s happening.
So this is the LED that shines underneath the chassis there which comes into the glass piece and lights it up so they can communicate to you through colors and such how the device what’s the situation of the device. A few minutes later. So in the office I was seeing me struggle here. Kudos to the guys from Dr. Dabber for really packaging this thing well. It’s almost like they didn’t want anybody to get in there. But, we’re going to observe the beauty of this device one way or another.
And the audience is going to love it and then the audience is going to give Dr. Dabber love and then Dr. Dabber is going to be like, “Yeah, okay.” They It’s okay, they broke it apart. So, this is what happens when you don’t have exactly the right tools because they have the screwdriver that is with a very specialized head, but also long. I have this specialized head, but not the long version. So, let’s have some fun together, everyone. Here for your audience as well.
It’s a I have a bunch of helpers here. They’re still standing outside of the frame joking around with me. For the audience, obviously, we do have more screwdrivers in Germany where the engineering team is. I just meet them from Canada up here in video calls, so clearly I could use more specific screwdrivers. But, that being said, I also have to say in a weird way, this is kind of fun. I’m really satisfied. Yeah, this is kind of fun.
One way or another. Yeah. We’re going to get through this. And I also disconnected the contact there. Just want to make sure that I am as I’m invested. I want to see what’s under that. Yeah, right.
Now, everybody, this is if this goes viral in the sector because everybody’s like, “How cool is the Dr. Dabber Switch Go? What does it look like inside?” I can see all of that without breaking my beautiful goal. Bam, you’ve come to the right YouTube channel. And yes, ladies and gentlemen, we’re getting through. We’re getting through. So, this unit was actually scheduled for more testing today.
And Dragon here, this is his nickname, is laughing at his Oh, no, no. behind off, yeah. What have I done? Cuz he was looking forward to testing it, but now he gets to test a brand new one because well, we had to sacrifice this one to the gods of knowledge. And guys, I better get more than five comments in the comments of this video. You engineers watching here, you should definitely write a comment because last time I did this was a while ago, let’s say. What not to do when opening the device. Yeah, how to prepare how to prepare your tools before you get into a teardown video.
Yeah. How not to open a switch. Yeah. So, for science, okay? For science. For science. All right.
Ladies and gentlemen, I got access. Good. Another piece I’ve found. For science. Science. Oh, yeah. There it is.
Look at this screw. Um so, definitely there is either there’s a mechanism to one way lock it, so you assemble it one way, but it doesn’t really come out the other way. Like you can’t really unassemble it the way it uh came apart. Uh so, it could be like that or I was just missing the exact sequence or missing the exact um tools to open it back up. But generally speaking, nowadays a lot of electronics are kind of put together in a way where it’s not even meant to come back uh apart uh because when like we have that with our uh latest launch, the Utillian 850, um it’s kind of like not really uh meant to fully come apart because if it’s defective, you just get a new one, it gets replaced. There we go. So, and I think this may be a little bit more of a vice like that.
Okay. So, here we go. Perfect. All right. So, ladies and gentlemen, that’s the heating element right there. And it’s like a spring, so it’s meant to push up against the bottom. So, I’m going to bring that a little closer so you can see hopefully with the lighting a little better.
So, you can see that’s the heating element. And that heating element So, here we got it. Um so, what you can see on the bottom of the heating chamber, and uh this is uh very interesting kind of cover. It’s mud, um but what you can see here inside that piece, I’ll get a little closer to the camera. Um, inside that piece is a component uh which to my understanding is the RTD. In most uh devices, they put it at the bottom of the heating chamber, in the center of most of the devices. Uh the uh Puffco Peak Pro is like that.
Uh the uh there’s a bunch of a bunch of different devices like that. Uh it’s the best place to put it, generally speaking, uh but not always. Uh like there’s a device coming out that we know of that’s uh positioned to the side due to unique half components here, but this one uh is generally the preferred place to put these. And these RTD, which is a resistance uh temperature sensor uh or detector, um these are actually very good um at um knowing the exact temperature. So, there’s two other factors as well. Usually, they use a metal, which is then the resistance inside that metal, which they measure through these two different wires. The resistance inside um is a factor of the temperature here.
So, if there’s a metal in there, usually they use uh very um metals that are uh that you can detect the differences of temperatures very accurately because the metal moves very effectively with temperature. Like platinum would be a high-grade one. So, um and because they’re touching the heating element, uh the resistance changes in the metal, these two wires measure that, and they measure that at a sequence. So, if you have a device that’s let’s say lower end, they would measure it let’s say every 5 seconds, every 4 seconds, something like that. Uh if you have a device that is very high-end, which would have a more advanced chipset and uh of course the uh the Switch Go would be would be one of them. Um they are doing that faster. So, I don’t know exactly what it is in the software.
Of course, that’s proprietary to them. I would estimate that is less than 1 and 1/2 seconds. Uh so, 1 seconds because that’s when it gets good when you can really get to it. Uh whe- when the chip set knows exactly, “Okay, this is the temperature half a second ago.” So, it can regulate itself. So, the temperature inside the heating chamber doesn’t run away. Um especially at the lower temperatures for um these types of concentrates, um the battery obviously has the power to change temperature pretty fast when it kicks in. So, you want to be able to know that and kick in.
All right. So, we’re back. Uh I just got the underneath cleared because there’s a lot of um black stuff. But, so now we can see the chassis’s that you got uh some uh this plastic is less temperature resistant. Um but, around the heating chamber, uh this is I can already see very rough molding marks, which is uh generally the hallmark of a plastic that is, let’s say, hard to mold in tight spaces. So, you see the thickness levels generally bit uh larger, and that’s generally a characteristic. And I would go out on a limb because you need lab tests to tell it for sure, but I would go out on a limb and say this is this is probably, I would say, 80% this is PEEK, okay?
So, PEEK is the best plastic you can use for temperature resistant stuff. That’s the kind of PEEK that uh most high-end units have from um around the I think the ArQ has it, the Mighty has it, the um most devices in high-end have that around the heating chamber because you can’t really get away with many other uh types of plastic or any other types of plastics. There’s like um a couple more, but they’re substantially more um let’s say, susceptible to temperature changes, uh changing the makeup of the plastic over time. So, the plastic starts warping and uh and then uh also off-gassing in some instances, which people don’t like, of course. Uh so, off-gassing uh off-gassing is of course not an option. So, um we have um So, here we got the crucible. So, this is there’s no electronics inside of here.
So, this material, based on my knowledge, is titanium, all right? So, this titanium bowl needs to be heated, and the temperature inside of it is measured by this temperature sensor, as I said earlier. And then you got these two wires that go back to uh the board, all right? Uh and then we get to and you can see even at the tip of these when I tore it out, of course these two stayed behind. So, most devices that have a temperature sensor, you need two extra wires. Those extra wires go to dedicated spots on uh the board, which feed the information back to the board so the board can do its computation. Um and um yeah, that’s That is usually a very good sign.
But, the moment you have that, you’re going from the range of something that would cost, I don’t know, less than less than, let’s say, 150 bucks, all right? It goes above that. Because of course these components are very intricate to put in, they have costs all to them, and of course the market is segmented too. So, when you have device Some devices are work differently, they work with calibration. You have that with If I’m not mistaken, with the devices like Puffco Peak, the original Utillian 8V2 is like that. Um where you have where you don’t need these two temperature sensors because the temperature ranges are calibrated. So, software knows, “Okay, I’ve done this like a thousand times in the test setting.
So, if I put in this much power, that’s what the that’s what the temperature of the crucible gets at.” And that’s how they get around it. Now, those are of course not as accurate, okay? And accuracy matters because in the higher-end, let’s say, anything above, let’s say, $200, um the accuracy matters a lot because you basically what these folks are trying to do what we are trying to do in our daily lives when we engineer high-end products for you we are trying to reduce the tolerance like tolerance is one of the main things in engineering that’s what I was telling you earlier about the glass bucket being so tight so beautiful people love this one is just so perfect right so when you want to manufacture things tolerance is always a key and tolerance also applies to temperature applies actually to everything it’s a universal lesson to take about the world nothing is really set in a specific space and distance if you if you’re geeky like me in physics and such nothing is actually in its place then you get into quantum mechanics and how particles are not really in their space and then everything turns into a simulation and we can laugh together that we’re kind of playing a game but getting out of that a little bit of philosophical intertwined so that’s an eating element this thing heats up and you can see on the sides as well bring it close and I hope the camera captures it or maybe I’ll try to zoom down I’m going to zoom down here folks so here this is a bit better for this shot what Dr.
Dabber calls dual mesh heating that’s sorry dual parallel heating that’s what they refer to I would assume because there’s a surrounding heating element and there’s one at the bottom two and the bottom one something that I think is very intelligent very smart very cool actually because they had to manufacture this specific part to be a little spring like so when this sits on top so when this sits on top the heating element touches the bottom to heat it while you see the circle at the bottom here leave space for the temperature sensor to not be directly touched because then because then you get a little bit into the nitty-gritty of if you’re applying heat through this directly to the thermometer, obviously the whole temperature is going to be up because the crucible could actually be colder and the whole thing starts not working perfectly.
So, there’s some QC that is definitely quality control that is definitely done here to assure that this doesn’t happen. Um but you can see that’s the system. And I’m going to tear this through just so you see just so you see. I’m going to bring it out just so you see it a little bit closer. Okay, so this is insulation. It’s not in the air pathway. So, in dry herb vaporizer this type of stuff would be completely behind this.
You always have to like put it outside of everything. Uh so outside of everything because you don’t want any of these. This is very good insulator, but you don’t want these little brittles anywhere close to you, right? This has to be completely locked and sealed away inside the device. And in this case it obviously is. There’s no way for this to land in the air pathway. These are completely different chamber sets, right?
But this is an interesting one for you to know because these are all very heat resistant and insulating. There’s air pockets in this mesh type material which help insulate the heat. So, that will result in you having a switch that has in a in this chamber something like let’s say 300° C at the highest temperatures, but the body of the of the Switch Go and here you can see the formerly very beautiful Switch Go. What I did to it so it can be in your hand and be perfectly comfortable. Um so just to bring that a little bit more further out so you can see it a bit closer for those of you that were extra curious and would like to know how these devices are put together. And each one of them is very beautiful in their own way. If you’re an engineer, if you’re into this type of geeky stuff, um you really get to appreciate because you got a get to appreciate how much effort it takes to put these together.
So, when you think about the cost of a unit, um it’s important to realize that look how intricately this meshes into twine. This doesn’t exist in any other product. So, these folks have to really design these, get samples, put them in the device, and then make it work with the software, calibrate it. It’s really It’s really a very difficult and uh time-consuming endeavor. And you really need smart people to do it, too. So, that’s where most of the uh costing comes from. So, if any of you are, let’s say, looking to uh let’s say, uh any types of devices, even electronics like smartphones and such, there’s a lot of work that goes into it.
So, if you love technology, it’s always a nice place to, let’s say, uh support the community. And there’s a different company, so I can say that, but uh they’re um they’re wonderful folks. We’re one of the best distributors. And um yeah, uh good folks. Did it turn on? All right. So, here.
So, now we’re going to be heating this, and I’m going to touch it for YouTube likes, okay? So, it’s So, guys, I’m going to move my finger towards it, okay? And burn myself if you don’t give me likes and subscribes, okay? Temperature sensor needs to be connected. No, no, no, wait. No. Let’s wait till that on.
Yeah, it’s pink. Uh it could be. Could be a Yeah, that temperature guy. You just press it once for it to start, right? Yeah. All right. So, now the temperature is set up.
And you guys can all see the heating happening here. And this video better get 100 likes or I’m going to touch this thing. And then you’re not going to have Nima anymore to make more devices or do great deals with wonderful companies like Dr. Dabber and the geniuses behind that. See that? How much it heats? So, this is basically a heating element.
But, this mesh this type of mesh coil I have seen in the um in the Don’t want to use that keyword because on YouTube they don’t like that. Uh but uh in other devices that generate a lot of fog I’ve seen this actually uh this type of mesh devices on uh cotton material that has uh liquids in it and that also does the same job. So, I’ve seen this type of heating element in those, but that’s basically how it works. And now I’m going to cut the video while I touch it. No, I’m kidding. Uh but yeah. I hope you guys like this.
There we go. Here’s a shot for people. And it’s just going to do that because it doesn’t know that the temperature is the temperature sensor is recording low temperatures. So, this is going to keep heating maybe even until the heater is like I’m dead. Let me go. Let’s see if we can burn it out. No, it actually capitulated.
Oh, because well, yeah. I disconnected the chamber. All right. So, good. So, we’re going to do a quick side-by-side test for the uh Switch Coil. We clearly assembled the unit that I had taken apart. No, I’m joking.
It’s a brand new unit. Uh sorry, buddy. We have many helpers here. My hands are look like this, so there’s like three people here to show you guys uh let’s say temperature ranges. And as I said in one of my other videos, uh, the we’re going to set them both to white and then we’re going to use a temperature sensor to compare them. And you can roughly get an idea. Obviously, if you wanted to do a super accurate temperature sensor, you temperature measurement, you would need specialized cameras for that.
We have one coming in soon. Uh, but right now I have this one which is which is fairly accurate. Uh, but uh, what the key is that as I said many uh, device manufacturers say like this is at 190. Yeah, you can measure it. You can say you’re at 190. And in reality, you’re not really at 190. So, I’m going to move the camera over here and we’re going to do a side-by-side.
So, this Touch the table. This is at white setting. So, it’s supposed to be how much is that again? 540. 540. So, it’s supposed to be at 540. We’re going to hold it there, see how high it gets. So, it’s supposed to be at 540. Just make sure the temperature sensor is really touching the bottom.
So, it kind of is at 510. And the other testing we did is pretty accurate with that. And you can see it went there. Great. The Switch 2 is already ready. The Switch 2 takes a little bit extra time to heat up. So, now we’re going to put this thing on.
So, it’s supposed to be also 540 on the Switch 2. Now it goes to 560. Back to 510. 515, 520. So, it seems like the Switch 2 uh, generally runs a bit hotter. Uh, it’s got a bigger chamber as well. So, you could get the let’s say illusion that the Switch 2 is like uh, thicker vapor, but that’s just because you can put it back in here just so we Wait, let’s turn it on first. Yeah, turn it on.
So, you could get the illusion that the Switch 2 is better at generating clouds, but it’s just that it runs a bit hotter. So, both of them are supposed to be at 530 or 540 based on the setting white standard out of the box brand new unit. And now we’re going to see again with the Switch Go. 515 520 522 it’s supposed to be 540. 524 so it’s 15° under and now it’s in the drop mode. Now, I think Dr. Dabber has a setting where it goes into drop mode by design. I’m not sure if this unit is enabled with that, but you can see that the ranges between the two are a bit different. So, the Switch 2 runs a bit hotter at the same temperature settings.
So, as long as you get the range between the colors, you’re kind of fine. Kind of fine. But you just find the best setting you’re okay with rather than just solely let’s say relying on the degrees temperature. So, you may have let’s say a different device like a Puffco or a Utillian or a Bomb or a Carta. I can name drop many of them now. The Crossing Tech Core and you may think all of them for 540 is the same. But a lot of times they’re a bit off and that’s the way the units in the market are.
The accuracy is usually where everybody wants to get to. So, if they say 540 that gets to temperature 540 and then just hovers between let’s say 535 to 545. That’s like the gold standard and we’re going to eventually do a Puffco unpacking as well a deep dive and then you can see for yourself. But generally speaking, Switch 2 I wouldn’t necessarily say it generates bigger vapor because of the heating technology. It’s got a bigger chamber, so you got to make sure you standardize how much you put in there. Uh but you got to also account for okay, it runs hotter, so that means you would compare one higher level temperature with one lower level temperature depending on how many degrees are between them. But in our test here, uh we were how many degrees off, gentlemen? 15. 15.
We were about 15° off between the two. So, if there’s about 15° off between uh setting between the two temperatures, so let’s say um white is 540, the other one is 15° down, then you would compare and same thing on the switch, you would compare the one temperature down with one temperature up of this, and that’s where you would get a more accurate kind of comparison. But in terms of standard deviation on the temperature, um I think they can be still calibrated a little bit, and as I know these companies, they’re pretty good at consistently improving the uh devices, making them more accuracy accurate. But uh keep in mind, you need the range, right? So, if you have a low temperature setting on the device up to a very high temperature setting on the device, you kind of have the complete range. You just need to kind of find whichever one you’re okay with.
So, it’s not like, “Oh, the device doesn’t function accurately at all.” No, it’s not quite like that. Uh you can still get what you need out of them. It’s just a display, it won’t be comparable with a different device because it could tell you it’s not the same temperature where it’s not. Uh and that’s okay. Um uh it’s very difficult to get these accuracies down, and all these devices are getting more and more accurate the more iterations they do, the more updates they do. So, generally speaking, uh this may be the best in the market. We don’t know yet.
As we do more tear-downs and more testing, uh we’re going to be able to tell say, “Ah, this one is more accurate than like I don’t know, like this device is more comparable to this other model from the same manufacturer because let’s say the temperature is a bit more accurate.” But um this is the first round of the go, so I wouldn’t also be surprised if the next round um let’s say is a bit more calibrated to reflect their own platform of devices. I hope this was useful. So, this is what the aftermath looks like and we’re recording this on a smartphone. Like people are wrapping up the set here. This is what the finished product uh looks like the beautiful Star Trek Enterprise Switch Go. Um and clearly it’s defective. So, as a little joke, we’re going to send this back into warranty with uh with them and they’re going to they’re going to have a good laugh with us afterwards.
So, thank you very much to everyone involved in building this.
