Thermal Imaging Camera DIY $110 VS Buy $530 || DIY or Buy

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Once you have such a camera, you automatically start to find more applications for it. Like finding leaks in the insulation of your house in winter. Or finding where your cat is hiding in your bedroom.

I like your perseverence with getting a good solution with your diy projects! Not an easy task to beat manufacturers in having great products!

I have the FLIR TG167. It does a good job. I've used it to find thermal "leak" around the house, monitored wheel bearing temps on my travel trailer as well as using it for monitoring my electronic circuits.

I was always curious how these worked. Very cool. Thank you for the high quality explanation!

The DIY videos are the best! And more appealing to a wide range of viewers 👌🏻

Personally a thermal camera + ZnSe lens has been invaluable to me in troubleshooting shorted boards. This made a thermal camera well worth it for me.

Ayyy, another DIY or BUY great! :))

You can always use a laser pointer to show where it's taking the readings or will that interfear with the reading, example laser points at the component imager reads temperate that way you don't need high resolution

I suggest: Lead acid battery desulfator, DIY or BUY.

Awesome work, dude! Thanks a lot! 😃
Even though it didn't work out, it's a fantastic starting point! I bet we're going to see a fully functional IR camera pretty soon! 😃
Anyway, stay safe and creative there! 🖖😊

Very cool video! My husband is the big fan of thermal imaging technology and has bought an infiray t2 to detect some thermal leak in the house, i will ask him to watch this video.

I needed an aluminium board and had no idea where to get it, so glad that they offer that now

If the surface is shiney according to FLIR, just put a piece of painters/masking tape on and you can then measure the objects temp.

Another great video from you sir Scott! :)

The DIY will always have advantages with his skill.

You could calibrate the DIY camera for use at a set distance and use it stationary. That way you could set something down in front of it and depending on the size and how far away it was, you could adjust the parameters to measure the X, Y of where the hot pixels are and know very accurately where the component is. It just wouldn't be a handy handheld tool for quick observations.

I’ve been waiting for this vid for a longgg time since I saw it’s preview on the patreon

As limited as the DIY option may be, I actually think I could use it for diagnosing hot spots on PCBs, though the drench it in alcohol method might work better.

scott you always amaze me
whenever i get new project i always find something helpfull on your channel
this time i abolutelly got what i looked for
im working with cars and i try to diy a lot of things
like year ago i made conversion from distributor to coil on plug for my honda
now im trying to make tire surface temp monitor
and literally all i need is simple small temp camera that will just give me temp across tire
and its exactly what this camera u made is suited for
as for what u said in the end about diy camera not having emissity coeficient
i think its all down to code
i can think of linear table in which u only need to put 2 values of real temp messured and 2 from camera reading
to calculate it and correct it i guess it might be a lot for arduino but i guess if im about to only use about 8 pixels per tire because more isnt needed it could work, the refresh rate is a bit worrying but maybe camera with less pixels could give me better refresh rate i guess 12hz is like lowest i could go but perfectly it would want to be about 20 so i can monitor the data with precission there is alot happening when u race a car and having a lot of data to check after session is never a bad thing

Very helpful video , I just joined a thermal camera company one month ago as calibration engineer 😀👍👍👍
And from the bottom we start from 80*80 sensor and at last we have 640 sensor of Ulis (a French company) very expensive 😂😂

Me : thinking thermal camera a really complicated you can never diy them
Great scott : hold my beer

The Flir E4 can be "upgraded" to the 320x240 E8 with a firmware replacement. Huge value, and you can Google it easily.

Great video! I was looking at building a cheap thermal camera so this was extremely helpful.

It’s uncanny how well your videos sync up with what I’m working on. I feel like just a few days ago I was thinking about this exact same problem.

that diy version is fricking cool great job dude

Adding a simple regular camera and adding edge enhanced overlay would only be a few $$ more, and would provide an experience that feels visually more higher-res. Also emissivity can be easily programmed into the software. These would be fun additions but given the price per pixel is much higher DIY in this thermal sensor, BUY is a good conclusion for a goal of a practical device.
I like your DIY vs. BUY series.

something you didn't think of: you can simply overlay a LCD without a backlight, over the thermal image, it may need another esp32, but might be worth trying, using another esp or controller would also mean you could lock it to the same framerate as the thermal camera, without needing one controller to do too much work

Amazing as always. Thank you for explaining how to troubleshoot with it. I am going to try that (because my circuits rarely work first time).
It is obvious that the components you tested for your DIY version are not granular enough for the kind of work you mentioned.
In my mind, that just means you haven't found a better camera module yet with a DIY price tag. If you could bring the DIY version under $250, then it would still be a good DIY win assuming getting better resolution.
It seems as if finding a module with DMA transfer and hardware DSP to handle the correlational computations would probably require an embedded MCU or PIC, so the price would much higher.
You kinda missed out for this video because tearing down the expensive camera could have shown what model components they use.

Your English has improved so much, bud. I'm so proud of you.

Nicce that's what i was looking for :) Thanks for it as Always awesome awesome video 💞

This is the reason i love Sunday's. GreatScott is gonna post something cool

This is awesome video. You're super genius. Thank you for sharing

Excellent video! I use my camera just to point out the problem area and pay no attention to the true temperature of the hot spot.

Great video. So valuable for my learning.
Does Flir manufactur their own sensor? It seems a thermal sensor should be available that has performance closer to the Flir one.

I think DIYing makes sense most of the time because you learn electronics while building!

Brow your all vidios r powerful thanx for sharing knowledge

Great video man.
Really appreciate your work and content.👍👍

GreatScott is the best at all time... learned a lots of things from you. thank you so much.

I think that diy imager would have some practical use in automotive diagnostics. Pretty cool.

I was literally just looking at some of these other day and now I'm trying to invent a problem to solve so I can order some from them 🤣

Everytime Me:
"I want to buy it (anything) but it's very expensive". 🤧
GreatScott!:
"Here is a cheaper DIY Solution" 😁

Omg! He is spiing me 🤣🤣 it was just yesterday that i was searching for a way to diy a thermal cam

Still an interesting and educational project even if it’s better to buy the commercial tool. Thanks!

I got myself a cheap off-brand version. The resolution is about half way between your DIY and the FLIR; I've used it now and then for troubleshooting and/or augmenting my videos with stills - as it cannot record video. But then, the price was also half way between your options: about 250$ IIRC.

I cannot understate the usefulness of thermal cameras in electronics design. At work, we have a design we've been making since 1985, and for some reason the output channels periodically just die on it. The why had never been figured out until we got a thermal camera recently. I was curious to see if there were any issues, and one of the components was rapidly cycling between room temp and nearly 250F when the output would go into the positive cycle of its waveform. On paper, the components used were perfect for the application, in reality we swapped a 110 ohm resistor to a 1k resistor and it fixed the thermal issue.

You are awesome man! Hope you do this forever

Sir you did a great job.
Thank You Sir now I can make one.

Bought a Flir One 1 year ago for my Android SmartPhone, it was only 199$ and is a Gen-III Thermal Imaging Sensor, it's very sensitive and has an extra 1080p camera built in as overlay so you can see details as well as the heat spots. Totally with 199$, but it does have a few drawbacks. Even though it auto-calibrates, calibrating can take some time. And it's prone to lock-ups and freezes, for example if you walk around with it from an cold area to a hot area, it can freeze up. Also since it plugs into the phones USB-C connector, it can fall right out of it.
They have fixed the notorious dying-battery issues (the earlier models usually lasted a few months, then the battery just flat out died), but for 199$ you get a cheap mid-range resolution sensor, and that ain't all bad. I use it to find heat leaks in my house, check for pipe-leaks in the houses piping, and fire risks in the chimney. I also use it as Great Scott does, to find overheating components.
It's also useful to detect thieves in the yard, something suspicious? Well they won't be able to hide from you - you can easily spot the hot body either of an animal (maybe your cat is missing?) or anything big and living in any dark areas.
Here is an example image I took of my 3090 card to see how hot it gets during idle process: i.imgur.com/WpuLjkK.jpg

I loved writings and also project

You made a thermal camera. That's awesome

Changing the screen or the screens library for a faster one would help and a better looking image can be had with bilinear filtering, I've even had quite good results with the amg8833 using this technique. I just need to pull my finger out and build one with the mlx90640 which I've had sitting around for 2 years! Great video though and I'd love to get a flir but can't justify the money for the real use I'd get.

Your videos helped me a lot ✌️

Great try, thanks for sharing

You've got to change the battery in that S7. Had the same problem with it drawing ≈0.2A and when I replaced the battery it was all fine.

Thanks Great Scott! This was fascinating! I wonder what IR LEDs or an IR laser would look like with your new or DIY camera?

Thank you for listening! Epic project!

Such a cool video! You are so brilliant! But for people like me who are not good at doing things, I choose to buy. Because now 200 can also buy only love that very good thermal imaging camera. I have infiray p2pro only more than 200, pixels have 256 * 192, motion capture is 25Hz.

Wow just when I was looking for one

You're really talented! But I prefer to just buy one.😆 I've just bought Infiray P2 Pro thermal camera. It's pretty amazing what I can get at such an affordable price nowadays!

Nice work! Also, you could upgrade It with a CMOS camera to get real image and mix both in same frame!

you are so much improved. Thanks fot your nice video

Good explanation, I really wanted DIY to win because of the high price of the BUY one. Turns out the high price is there for a reason this time in DIY or BUY.

Yay, another greatscott video!

Its amazing tutorial :D! , Thanks for the videoo

Why not get one of those "seek thermal camera" which attaches to your smartphone

Get hold of the ESP32 camera module, remove the IR filter, revamp the colors to give IR representation.

I just bought an Hti301 from aliexpress. Cost was 600usd. 384*288 pixels. And with the app thermapp it is friggin' amazing!

So I'm pretty sure I've seen a guide for such a project on Adafruit Learning System. I don't remember which sensor it used, but I'm pretty sure the dev board in use is the CLUE (micro bit shaped nRF52840 cortex m4 at 64mhz, with TFT and a bunch of sensors)

Legend will always cite the source of data they used, that's why i subs this channel. fascinating

Really a great idea. A shame to have to work with so low rez. I'm wondering, since a brand new is 450€+, what precision could you get by spending let's say 250 on that kind of project ?

I think you can change the emmissivity coeficcient, if i remember correctly. i used the MLX sensor for a school project and when i was writing a python driver for the rpi i stumbled over the setting. but i don't know if it is in the adafruit driver or the original Melexis cpp files.

I love these videos

Sigh, looks like I'm gonna have to buy the actual camera. Thanks for the great info and soothing voice as always.

I need to make an eFuse circuit for my farm irrigation system. Your video on the subject is the top rated video. I was wondering if you could do an updated video on the subject. Thanks

Some smartphones have a IR camera built in, there's even a module you can buy separately and plug into your smartphone.
Thanks for the great comparison! Now I'll definitely won't try to DIY it ;-)

Out of interest could you add some form of laser or a seperate camera to measure the emmisivity coefficient of the material to automatically apply that to the final image and get accurate temperatures?

Nice Job with this comparison and I agree with you - Buying the Flir at ~$500 is a more useful and reliable tool - which is the stated goal. Otherwise, it is still fun to DYI, and get the experience. Thanks!

Hello Scott it is far IR that is based on Temperatur other IR cam using near IR. Like secure cam..

Why not use a visible spectrum camera module and overlay the thermal map over it?

T H A N K Y O U!
I have the components, but never got around to building one. Now I guess I have to!
Definitely has to be easier than figuring out that Triad Spectroscopy board I bought 😖

Thsnks for a reduction in the pain of doing your own ir camera

Been monitoring IR sensor prices for some time now. Always too expensive and resolution too low. However I have several old cell phones that are only collecting dust. Maybe it's time to dedicate one to permanent thermal imaging via one of the add-on modules. Another Great Scott DIY project perhaps?

Could you cheaply buy a bunch of low res sensors and use software to overlap them for better res and refresh rate?

Can you combine the low-resolution thermal image with a higher-resolution visible-light image?
That way, you have *some* idea of what you're looking at.

FLIR used to make some cheaper version of their thermal camera that actually used their high resolution sensor, just artificially limited. The full sensor resolution could be restored with a firmware hack!

my favorite serie

You should have compared your camera with a commertial camera with the same resolution, for instance FLIR One (plug in for the smartphone).
Actually, can you make a DIY plugin thermal camera for a smarphone instead of a handy one?
Anyway, great video. Very inspiring!!

One option you didn't explore was the hacking that was done with the SEEK thermal imaging cameras. They are very affordable IR modules with a USB interface, but it's all proprietary. I think they managed to crack the older models but the newer models only produce a raw unprocessed image last time I looked into it.

Super video!! I like your channel!!

Go for cat62 GSM. For 600 bucks you get telephone with pretty decent flir camera. My wife uses it to generate heatmaps of buildings, but I've tested it for electronics and works great. It's more expensive than flir you have, but you get added bonus of very rugged telephone which can survive extremely harsh conditions

I'm now curious about the extra cost of a higher resolution sensor and display. How much more resolution would you need to replicate FLIR, or make it usable for electronics diagnostics?

It looks like you could just change the code to add some of those features you mentioned and probably use a more powerful chip like a rpi.

Maybe you should have used a raspberry pi zero instead and added a cheap 3M pi cam to overlay over the thermal image. it would have been a bit more expensive but would make it perfectly suitable for your use case.

Cost on these is still high, so the sensors must be expensive, but not as much as the Webb telescope which will have the ability to look back in time into a specific IR wavelength for doppler shift.

Two other buy options: you can get USB C and Lightning FLIR attachments for your phone, which cost way less, but then your phone is the screen, you can easily save and share images and video, and eat mor control. You can also get smartphones with built in thermal cameras, although they’re typically targeted towards construction/engineering folks and while they’re typically very rugged,, they often lack other features for regular phones in that price point

For all those interested in acquiring a thermal camera: UNI-T has some budget options starting at around 130€ with a resolution of 120x90 (10800 pixels). However, they lack the handy Flir feature where it superimposes edges of the visual world (FLIR feature a normal camera next to the thermal one in its thermal imaging units). Aside from that, you can get Flir usb addons for smartphones starting at around 220€ that feature this image mix, tho the cheaper models do come with a lower thermal resolution (80x60) than UNI-T's.
I can also recommend such a tool for renovations and thermal isolation of pipes, windows, and so on.

Those cameras are long-wave IR (LWIR) cameras, they are sensible in range of 7-14 um, but not from 700 nm as you stated.

Well that's a interesting idea. What about trying to convert a simple normal camera sensor in a termal one . Just a simple question

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