Its not the video thats pointless, you just dont know shit, you brag about intelligence and knowledge in every of your comments, but you dont have both Kind of weird mate
NGL, I have the same type of thing going on. I have multiple workbenches, and there's a pair of sidecutters at every one. Electronics, casting, 3d printing. I kept always having them at the wrong bench no matter which one I was using until I bought a pair for each lol
Well.. if you only need 2-3 bits for a job it does make sense that you don't want to constantly change the bits. And it still lets you be versatile for many jobs where different combinations of those 2-3 bits are required for each one. Also. If I recall correctly. The whole point of replaceable bits was to keep costs down in factories where robots and human workers could toil away using the same type of bit endlessly. Endlessly replacing that bit with a new cheap one as they wore out instead of a big new and comparatively expensive screwdriver each time. So it does make sense in multiple ways to have multiple bit-holders. :)
After 10 years mine gave up and didn't switch on anymore. I purchased another one from ebay- a metal one. What arrived was trash. Astonishingly, I was able to transfer the display, pcb and housing to the old chassis. Everything was the same. I'm astonished the parts we're interchangeable. Thanks Clive for giving me the confidence to even attempt the fix rather than send both to the bin
I worked for a company for a a number of months repairing precision measuring equipment including calipers, depth gauges, height gauges, micrometers, you name it. Mostly mechanical, but also electronic versions. What you were able to surmise and figure out from what you saw, without knowing the sorts of things I was taught during training, is amazingly accurate. The main problem with those digicals is once they go wonky, there is no currently available way to repair them. With the analog ones you can always regrind, retension, rerack and realign, but the digital ones go in the recycle bin.
@@johnf3326 it the 2 PCB'S that are the important bit, and there going to be made by a third party, PBCway springs to mind, but there more company that make PCB's and by the nature of the device, any take making that part, will have have high tolerances, and thing PCB's just have the stable don move shape much if at all unless being cooked, and the finished machine is self calibrating anyway knowing what it's own moray field pattern, as the two parts move? would be intresting see fails where manufactured, to the number fully working ones, not including one build as lemons?
I've often wondered how they made these things and managed to make them so cheaply yet with an incredible degree of accuracy. Thanks for making this interesting video.
this might be okay for home use, but for more applied uses, you might want to get something with a bit more resilience. i can't see that thing lasting too long for someone operating a lathe.
@@eatmywords yes totally agree. I've got a set that are better than the ones in the video but still cheap. It's only for DIY use but I wouldn't use something like that for serious and everyday use.
@@eatmywords Yeah, clearly, if you're doing lathe (or any kind of workshop tools) work, you won't be using 5 dollar calipers from Amazon. That would be like putting Walmart tires on a supercar. But while my calipers at home are a tiny bit better, going down to hundreds of a mm instead of just a tenth, it's still a pretty cheap one, and works perfectly well for anything to do with 3D printing (printers don't really get much accuracy beyond a tenth of a mm anyways), or any other random things I happen to come across and need to measure I might have to eat my words and buy a better one soon tho, now that I've bought a cnc machine. But I don't really have any plans on using the cnc for anything super critically accurate anways.. for now
@@Excludos i've used 20€ catapilar for my years in CAD school (i'm not sure howto translate it to English but basically, i mesure sizing of part for a broken machine, and then i just create it with a fraiseuse Tourneuse) and it was actually quite good compared to my prof high end thingy, as long as you never drop it, it's fiiiiine
Would have been better if he'd looked up Vernier scale on Wikipedia. That's what's really going on at 12:28. Before electronics, it was purely a visual aid, and it's fascinating how it works. It's the reason I don't bother with the electronic ones. Yes it takes a little more mental effort, but it's a mental effort that I find quite enjoyable simply because it's so fascinating.
I looked into this technology a while back. Essentially what you have is a capacitive linear position sensor. It's not a vernier. The principal is that the teeth of the narrow comb on the sliding PCB are excited by the chip using sine waves. These teeth are in interleaved groups, and each group is fed a sine wave at a different phase. These teeth capacitively couple with the large comb on the measurement rule, which in turn capacitively couples back to the single long receiver bar back on the sliding PCB. The result is that the output from this bar is another sine wave, and critically the phase of this sine wave is determined by the position of the fine teeth relative to the large teeth. So a full 360˚ of phase corresponds with the pitch of the large teeth, 0.2 inch in this case. The chip measures this phase shift to determine the position relative to the set zero. So a 18˚ shift corresponds with 0.01 inch for example. In fact in these cheap calipers it's all done digitally. The excitation is done using PWM coded sine waves, and in the example here they're fed in differential pairs, so that's 8 signals, four pairs, 45˚ apart. The output is then very spiky, but with a sine wave envelope which is recovered by digital filtering. Somebody scoped this version a few years ago - see web.archive.org/web/20120328090506if_/www.yadro.de/pics/hp-logic-analizer.jpg. You can see the four PWM sine wave differential pairs in the 8 digital traces at the bottom, and the single output signal before filtering at the top. Just imagine the peaks of the envelope of this signal are 0.1 inches apart and the signal shifting across with the slider and you've got the idea. The reason for 56 small teeth rather than just 8 is to multiply capacitance and therefore multiply the signal output, plus averaging of any small physical inaccuracies in and impurities around the teeth. So each set of 8 small teeth in fact precisely line up with each pair of large teeth.
@@huntma3787 I have these same inexpensive calipers and they remember where they are when you turn it on too. Since it has a move to wake, as soon as you move it and since it has the last position stored it knows where it was / is. Now whether the Mitutoyo is really absolute or just does the same function, I don't know. I would tend to think it's the same as these. Now, if you took out the battery, moved it and then re-installed the battery and turned it on, that would tell you for sure if it is absolute or just storing it's last known position. But good question!
@@huntma3787 as long as they have a battery the cheap calipers never fully turn off.... all they do is turn of the display. so they are essentially always keeping track on where they are. other than that they are purely relative. though amazingly quick as demonstrated when they didnt miss a pulse during the rapid movement. but that also means that they eat batteries like crazy.
@@TheScarvig A Mitutoyo (if you get an authentic one, not an eBay counterfeit) doesn't eat batteries the way the $10 calipers do. It can go for years on one battery. I assume it has a small flash memory component that the cheapo models don't have.
@@jpdemer5 the issue isn't storing the last value... the MC inside must be active to read the capacitive encoding to detect the movement and wake up the display automatically. if it only wakes up from a button press then its easy to send it to deep sleep, but then you wont keep track of the position while its off. they could tie the wake up to some other passive component that reacts to the movement of the jaws, but then still the MC must wake up quick enough to not loose any increments on the scale. so thats an awful lot of engineering for an, imho, pretty useless feature... just zero the damn thing after turning it on!
When these calipers came up we tested them with some small drops of water under the slider to see that they work with capacitive sensors. The instrument was in fact confused. After little drops had dried out it worked normal again.
Mine got wet and I had to wash it out and let it dry. Was completely goofy until it dried, as good as ever once dry. I prefer the older ones from Harbor Freight (in the US), but the new ones are all plastic, sadly. Tough too - I have dropped it a number of times.
I use the original visual Vernier scale only, as they existed before electronics. I never have to worry about liquids (except the kind that could etch the Vernier away ;)
@@TesserId you also need to worry tremendously about the mechanical characteristics of the metal the scale was printed on, whereas electronic ones (especially the advanced models from trusted brands) don't. Everything is a balancing act which depends solely on your use case.
When I saw Ave review one of these cheap calipers a couple of years ago, he almost made me feel ashamed of myself for owning one. You've restored my self esteem and confidence. Thanks Clive. Keep your beard in a vise.
@@bigpjohnson Although this super simple design probably doesn't allow it, cheap designs resort to trickery. For example, my cheap bathroom scale remembers past measurements to give fake consistency. It's probably only accurate to five pounds, I mean I can literally grab a weight and it will claim I weigh the same, to the tenth of a pound.
Cheap calipers are good for some things but they can be a major major waste of time. Really you should own a beater pair and a good pair from Mitutoyo or similar. There are places you won't want to stick the Mitutoyos but they are a decent source of truth. Also a caliper that only reads tenths of a mm is probably not something I would trust even for 3D printing. Really you want an extra decimal place of precision past the accuracy you're aiming for.
The ending bit where you moved it as fast as possible to prove it wasn't a relative measurement has convinced me to buy one of these. The plastic, even on good models, always felt like cheap junk to me and I was sure there's no way it's actually as accurate as it wants you to believe.
"I wonder if this pops off". I've found that with (in)appropriate amounts of force and leverage anything will "pop off". The tricky part is getting it to pop back on again. : )
A tire storage place managed to hire someone who fit this perfectly On his second day, the local newspapers told the story of how he had succesfully removed all 4 rims..... Without removing the lug bolts....
So the capacitive fingers do work exactly like a traditional vernier scale, with the wave of lined up fingers moving across then restarting at the beginning again.
Indeed. I always thought these things were wrong to call themselves 'vernier' calipers because they're not read via a Vernier scale like the typical non-electronic ones... but it turns out they do still use the Vernier scale principle behind the scenes. Nice!
I'm sitting here, with my jaw hanging open, laughing at how accurate these things are even after taking it apart and jamming it back together. I bought a metal one a while back, for €7 at a store called Action (in NL). It has pretty much the exact same display, buttons and battery holder cap, but in silver/grey. I'm just amazed now I learned how they work, I always thought it would be like a little scroll wheel inside, but didn't expect it to work contactless. Amazing!
I've actually got one of these lol. I scratched it up a bit, it does have fiberglass in it. Still no idea what they marketed is having carbon fibre, these things cost like 10 USD...
There’s GFRP (glass fiber reinforced polymer), which is relatively commonly seen nowadays in high strength applications. There’s also CFRP, which is basically the same as GFRP except it swaps carbon fibers for the glass fibers. It’s not the woven carbon fiber stuff people think of when they hear “carbon fiber”, but it’s still carbon fiber
It's worth keeping in mind that the flex in these calipers means that it's difficult to measure beyond .1mm without influencing the measurement just by the amount of pressure being put on the caliper.
More advanced calipers and micrometers have a wheel or knob with a clutch to close the jaws on the part being measured. The clutch is adjusted so the user can't apply more than a certain amount of force before it starts to slip. That way the pressure in the jaws is always the same, and the measurements are consistent. I have a $20 electronic caliper from Harbor Freight that has a wheel like that.
Agreed - repeatability and accuracy of finger pressure is pretty unreliable. I file small components to sub thou" accuracy so this particular instrument is not for me. For about three or four times the price, the stainless option is still great value and serves me well. They also have a variant that can be switched to display fractions of an inch - great for old fossils like me ;
@@233kosta quite so in most cases, These work well for me for small internal measurements, as well as external. Fitting steel reeds into slots with about half a thou clearance. Handy to be able to do both with the same instrument. In case you are wondering, I make new reeds for concertinas. Just to make it more fiddly, some of these are also tapered both in thickness and width, along their length.
What I was told during my apprenticeship at a machining shop was that calipers are only accurate to 0.1 mm for measuring, but you can use the added digit (on professional calipers) to see about where you are with regards to the measurement. What it means is that if you had to measure something to 10.5 mm +- 0.02 mm you could not use the calipers to do that, you'd have to use the micrometers. The true accuracy and precision of a caliper should be stated in the user manual.
A buddy of mine used one of these to make an RDO for his drill press. The serial interface on these is the real secret gem. There are so many potential applications for it.
@@kaikart123 I came across a page with the hack and protocol, but since I had no interest in it, I didn't bookmark it. That was over 10 years ago. So, I imagine they know even more by now.
I have bought a few of these, only to find out the serial output does nothing on them. Not a peep, not even with added pullup resistors. So beware of that. The PCBs look exactly identical to these.
2:26 You can use the back of the head to measure distances too. Works kinda like the depth gauge, but the larger flatter surface can be useful to keep your measurement square.
I would love to see the differences in the 0.1mm precision calipers and the 0.01mm precision version. I'm curious if it's just more lines on the respective pieces or if it's done inside the processor itself.
I'd assume it's both. Like considering the actual sizes involved on two paralel surfaces i'd say they use differwnt tech process to make pcb more accurate, like using different photoresist(the better the "resolution" at which it can "harden" the costier it gets), different mask tech(i don't even know what they do it with in high end machinery, maybe some fancy pants uv projectors with complicated optical system), better, more accurate enclosures, etc
As user of the old visual Verniers (never bothered with electronic ones), it's pretty obvious that it would either have to be an order of magnitude smaller or an order of magnitude more lines. If it were to turn out that they were the same (which they might well be), is one rounding for a cheap display, or is the other algorithmically advantaged? With a computer science degree, I'm trying to imagine what that would entail.
Ah right! Was wondering why anyone would reinvent the 'wheel' (processor) when they have existed off the shelf for 20 years and are likely now dirt cheap .. makes sense that the cost would have been cut in the encoder resolution/accuracy, and so overall assembly.
@@JimTheZombieHunter We've pulled apart both 0.1 mm increment plastic (carbon fiber) units and 0.01 mm increment metal units. They appear virtually the same inside. The difference is in the display, in that the plastic unit doesn't have the extra digit. Presumably because the plastic one would not have the repeatability of the metal caliper. Maybe they are more precise in manufacturing the pads of the unit with higher resolution.
@@TesserId I _don't think_ that would actually be necessary. Additional precision and/or more lines of some sort may be required (though maybe not; they may just not display the extra digit on these, but be capable of calculating it), but even if so... well, I'm not sure, but I suspect there could be tricks done by having just different offsets on some of the things.
I would imagine that, being that the wavelength of the sliding part is variable, that they are effectively self-calibrating, because moving them will emit a certain wavepattern at a certain place which the chip can then corrolate to a position along the length, even if you thrash it really fast as soon as it moves it knows exactly where it is. Also, reading if the waveform is lengthening or shortening will tell it what direction it's moving in with no other moving parts. Bloody genius.
I use digital calipers at work every day and I appreciate the amount of time I save compared to reading non electrical ones. Instant numbers showing up is such a time saver
FWIW, I have a Mitutoyo calipers (about $175), plus several mechanical micrometers (one of them a Mitutoyo as well) and a digital mic that goes to half a tenth, plus about 4 Harbor Freight digital calipers. I've never found any inaccuracy between them. All four of the $20 HF calipers measure my inch standard at 1.000 inches, same as the mics and the Mitu. So I think the accuracy is there as well as the precision.
I've been there. I got tired of replacing batteries every time they sit idle, so I just ponied up for a few pairs of Mitutoyo calipers...now I replace batteries after YEARS...not WEEKS.
Neat. My $10 set has a solar panel to charge the battery. I left it for a while in a box and indeed the battery had died. As soon as I went outside it turned on.
I've some of these that are coming up to 3 years old and are still using the supplied battery. I've also got one that will eat the batteries quicker than pacman. Chinese lottery.
now only if there was a way to feed that data of a control board for feedback of CNC as most low end board does not have leaner encoder feedback but if it was there then all low end CNC (small PCB mill , 3D printer , Engreaver & Laser cutter )would become super accurate
@@sourcefollower It doesn't matter how rigid the frame is if the X,Y and Z axis screws aren't accurate enough in their pitch to produce a resolution of at least .02 mm. There are many other factors that apply more than a rigid frame, like squareness of the axes and backlash in the screws.
@@gangleweed If the CNC machine was using scales along each axis to position itself, it wouldn't need to rely on counting turns on a lead screw. Move 6mm, would be move X position on scale - not turn (6mm/thread pitch) rotations.
The mechanical bits are important too. Straightness, parallelism, rigidity, stiffness, etc. They also have an impact depending on what is being measured. Having a locking screw and being able to use the sharp metal tips of the interior width gauge to transfer point to point measurements can be really useful. Thanks for the video!
I was just typing a comment at the end of the video suggesting that he should have done so, and then realized that he was doing it as I was typing! lol
I have the exact same calipers and they're totally adequate for my needs. However here's two tips; 1) Remove the battery when it's stored, otherwise it may go flat. This may be due to carrying them in my car. The jolts may be switching it on too many times. 2) If it starts to read just half of the true measurement, just remove and replace the battery. Reboot! Thanks Clive, that was very informative.
The batteries just go flat because there is no true power switch so there is always a small parasitic loss as the circuitry inside constantly monitors for the pressing of a switch. It's the same with all sorts of devices, like remote controls which do, of course, have much more batery capacity. I too remove the button batteries from these type of devices when I put them away.
Just thought you would like this random bit of info, these are used to measure the thickness of the biscuits made at a factory I did a job at recently.
:) I find the use of a pair of precision calipers to measure cookies hilarious, but it's even funnier in America, our biscuits being big soft, squishy fluffy irregularly shaped flaky things.
@@tedhaubrich This particular biscuit company had imported a machine from italy to make the biscuit dough to relieve the poor lad who hand made it every day. The machine was a giant and cost £100,000 or so. It couldn't make a flat piece of biscuit dough. I told them it wasn't a surprise as it was a machine designed for making pasta.
Very interesting. I use mine all the time and was always amazed at how repeatable (and probably accurate) the measurements were. Thanks for explaining how it works!
... I never thought or be dared tacking mine apart I would brake it and could never put the thing back together ... but it's nice seeing what's in side 😂😝 ...
Explanation of how it can read so precisely while using so few contacts: being advertised as a Vernier caliper, it is most likely using an electronic version of a Vernier scale. Vernier scales work by using a main scale for a larger unit, and then a smaller scale for a subdivision of that unit. the smaller scale is divided into lengths equal to the main unit minus the subdivision, so if youre between ticks on the main scale, each tick along will bring the ticks of the two scales more closely into alignment by precisely one subunit. this means you can find the scale's reading by counting along the smaller scale from the main unit you measured until you find the point at which the two scales align, and add the corresponding number of subunits. It's easy to see how the circuitry displayed would be able to achieve this, and also explains the slight mismatch in length between the groups of contacts on the circuit board and the capacitive strips on the body.
That's what I thought as soon as the two scales were aligned. The circuit contacts are physically the same as mechanical Vernier callipers. I see no need for any complex 'waveform' or binary encoding of all of the elements. I don't have anywhere near the knowledge of electronics as 'BigClive', but it is basically a mechanical device with a digital output instead of a physical one. I have watched other videos of his as I have the same scientific curiosity about almost anything.
When I saw it advertised as Vernier calipers I thought they were just misrepresenting the product. But when he opened it up and I saw the pattern, I assumed it was some kind of electronic version.
I bought a cheap steel digital calipers years ago after buying my first 3D printer. It's since been probably my most used tool. I love em! It's cool seeing how these take and record these measurements and it hurts my brain to think about the calculations required to interpret the signals coming from that capacitor array thing.
That skewed capacitor array works exactly like the vernier scale on traditional calipers. Detecting which line matches up gives the least significant digit, while counting the large marks passed gives the first digits. Write the two halves after each other, then apply the inch/mm unit conversion. Of cause, having 8 measuring channels suggests the use of binary digits instead of decimal ones.
This was like watching one of those nature documentaries where you see a baby bird being eyed up by lizards - you're so sure it's going to get eaten. There's no chance it could survive.... is there?
There is a fourth measurement you can take with calipers like that that most people don't realize. Aside from the tail, you can also use the opposite end. Since the two parts are flush at the "Left" end, you can measure a step.
As a mechanical inspector on a UK military aircraft project, who uses Vernier callipers on a regular basis (not ones supplied by Lidl may I quickly add). This strip down has been so interesting and enlightening about an item of measuring equipment I've taken for granted for so long and often wondered how they actually do work. Thank you so much.
Re the very last bit: it’s actually not just tracking it at jphigh speed - the capacitive vernier system provides an absolute position, rather than relative. Or at least, it’s absolute within the repetition horizon, which is probably something like 30 cm. If they get super long, you might be able to get a situation where it’s off by , but never by a small amount.
Im pretty sure you're wrong there. That's a simple capacitive interference sensor with a repeating pattern. It's definitely a relative position sensor and needs to be set to zero by the user at some position. The reason it doesn't lose track of position is because the sample rate is faster than the speed you can move it, quite trivial these days with very high speed MCUs and the pattern repeat being large, about 20mm long. (Edit) sorry it's 20mm long for half a phase so maybe 40mm long for a full phase.
Just a FYI, these “cheap” callipers don’t turn off completely. The encoder is constantly drawing power to remember its last position, allowing it to turn on when it’s moved. Subsequently, the battery dies fairly quickly when the device is left with it in... I’ve started to store mine with the battery removed.
@@rushilkisoon Indeed, spent about twice as much to have a mechanical one (which turns out to be more accurate AND precise, bonus), because the empty batteries annoyed me fast.
I got a expensive metal type for more accurate measuring and this cheaper digital one for simple parts. Quite weird but I got it for like 2 years now and the battery is still good 🤔 never take it out when I store it.
@@mrclucker1969 exactly what it is. @bigclivedotcom if you look here you can see the original analogue explained. ua-cam.com/video/rdFwZaRgO8s/v-deo.html
I agree. By making the spacings between the moving strip and the spacing on the ckt board different, they are able to generate a 'pulse' much more often than what can be practically printed on the PCB. I'm sure the PCB manufacturing can't space close enough together for the accuracy desired, so they used this variation of Vernier scaling to increase the resolution of the pulses.
I've been using one of the slightly-better-but-cheap ones that go to hundredths of a millimeter. Always wondered how they work, thanks for taking the time to take those apart! I've found that hundredths of a millimeter are really useful (almost mandatory) in 3d printing since filament widths can vary by brand, anywhere from 1.6 to 1.8 mm. being able to tell 1.72 mm filament from 1.78 will often make or break a print since the volume of plastic being extruded is dependent on filament width. Also getting that first layer to come in at exactly .15 mm (or whatever you're printing at) is also really important.
Have the same and works great. This technique could be used for digital (and motorized) potentiometers for audio mixers. The zero function can be used to set a memory location to be able to move to exactly to the same position. When motorized, it can be used to fade-in to exactly the same position. Very clever design, love it. Thank you for showing us.
The clue is in the phrase "vernier scale" which is, according to Wikipedia, "a visual aid to take an accurate measurement reading between two graduation markings on a linear scale by using mechanical interpolation; thereby increasing resolution and reducing measurement uncertainty by using vernier acuity to reduce human estimation error": "The vernier is a subsidiary scale replacing a single measured-value pointer, and has for instance ten divisions equal in distance to nine divisions on the main scale. The interpolated reading is obtained by observing which of the vernier scale graduations is co-incident with a graduation on the main scale, which is easier to perceive than visual estimation between two points." en.wikipedia.org/wiki/Vernier_scale
I spent a lot of time reading verniers in my first year at university. I haven't done it since, but I remember the principles. I had never imagined an electronic vernier, but here one is, and what a good idea!
@@zh84 The electronic ones aren't Verniers at all, although you might think so from looking at the circuit board. They rely on an AC signal that changes phase as you move the slide.
That's what I was thinking. The small contacts on the pcb correspond to the small scale on a vernier that gives the fractional measurement. Quite clever.
I would think so, but each 8th small contact is connected in parallel. So there's effectively only 8 small contacts that cover only 2 big plates on the other detail. This means that there're at most 2 small contacts that are located over the border between big plates and can sense anything meaningful. Seems not sufficient for required accuracy at the first glance. It's also not clear why to repeat this circuit so many times and connect all on parallel.
8:24 : The mystery button next to the inch/mm one used to allow you (in the inch mode) to switch between decimal and fractional values e.g. 1.500 → 1½ the missing button on the OFF/ON and ZERO buttons row used to be HOLD.
I watched this video over a year ago but came back after measuring a soapy part of my shower. The read measurements went haywire: 0 was 0 but 20mm was 80 something and then 30 was 40 etc. it just bounced around! I thought of this video and realized the contacts must be contaminated. A quick tear-down and wipe with an alcohol pad and then re-re-watching this vid very close to understand where the pieces went - thanks Clive you saved me a few days without a micrometer and $9!!
I have the exact same caliper and am very impressed with it, after pressing zero and then pulling all the way back and also reading 1563mm. I use it mainly for my electric bike conversion project while also adding mudguards and other accessories that need them to accurately measure fiddly nuts and bolts washers without the guesswork and are easier to read than the manual steel version which is difficult to read after time and tarnish.
The clever thing of these is that they don't track the movement. They just read the position they are currently at. That enables them to still show correct values after moving the up and down at light speed haha :D Great video!
The one I have is a Pittsburgh 'brand' from Hazard Fraught I picked up in the states for $12.99. The meter part is virtually identical (including buttons, battery compartment and screw locations) except it sports a metal thumbscrew in the side that's meant to serve as the 'hold' and has a metal thumbwheel next to the plastic thumb grip. The rest of the unit is steel instead of plastic. Great little tool for the price.
I bought BOTH these exact same models from China as soon as they became available. At that time I guessed they use the usual principle of vernier gauges, resolved via capacitance measurement - as Clive has now revealed. They are amazingly good value for money - especially when your eyesight is beginning to fail and steel rules and vernier calipers are becoming more difficult to read!
Thanks a million for this video. I'd taken mine out of a drawer for an upcoming customer visit next week, and left the calipers on my desk. My seven year old picked them up this evening, waving them around like a sword stabbing things in my office and somehow broke them into pieces. I watched your video and was able to reassemble them in a few minutes. They still work great and now my sword is fully functional again. Thank you!
I held onto my first-bought 1/20th mm vernier caliper for more than fifty years now, and counting. Still works great, and I never need to worry about the battery being exhausted.
Best tool ever. I have the 8"/200mm version and it measures down to 0.01mm/0.001". Sometimes I just wander round the house measuring random items because I can.
I keep an extra set next to my chair where I watch tv. It’s amazing how often I am fiddling with some gadget or idea and end up using them. I have one in the basement workshop, one in the upstairs craft room, and one in the family/tv room.
So I have a somewhat more expensive steel version of this that goes down to hundredths of millimetres, but the black plastic bit with the screen is absolutely identical to this one! I was always really surprised about how accurate is seemed to be, glad I know how it works now.
I wanna see an Oscilloscope on it, this teardown was very interesting and I'm really intrigued now to see the waveform on those fingers to get a better understanding of how it works. Is the software comparing the phase angles and timing coming back from the fingers?
I think it is just a Vernier. the chip keeps track of number of steps passing by, and then uses the vernier magnification; the strongest signal, or is it lowest capacitance, is where the best line-up is?
Yeah, I'd love to see a scope on this, too. Maybe this is where we ship it off to Dave for a whiteboard treatment, too? :) (Not that Clive wouldn't be capable of that, I just imagine he'd get bored, because it wouldn't be destructive enough. ;) ;) )
I bought an "all metal" digital caliper over 20 years ago for about US$10-$15 and it's still working fine and with no "slippage" requiring periodic resets. With excellent accuracy and especially repeatability it's been an excellent tool. It was just a no name "Electronic Digital Caliper" that I got from Circuit Specialists. Even the plastic box with formed foam cut-out for the tool is still 100% serviceable. No sign of hinge deterioration. Some things just pleasantly surprise you.
Oddly, I have just bought a very similar model from Amazon (the ‘ruler’ part is completely identical), but the three buttons are along the bottom - it was a toss up between them being above and below or just below, I went for the cheapest. My thoughts as I was watching this was a manufacturer churning out these with a few slightly alternative cases so companies rebadging/ branding them could appear like their offering is different. It’s certainly not so uncommon in electronics these days. Writing that thought down though, I wonder - considering all the unused connections - if the board is even more generic and gets used for other related devices, we can argue plastic over metal, but is a metal version necessarily (electronically) any different? Even the level of accuracy could be down to the software an otherwise identical board is flashed with.. it wouldn’t be the first time the cheap and the premium model turn out to be the same thing under the hood, and the array of choice actually leads back to a single manufacturer carefully differentiating one product.
Right you are! The number of decimal places relates to precision, not accuracy. An instrument may be precise but not accurate. Conversely, it may be accurate but not very precise.
It is repeatable. To obtain accurate measurements one has to have intimate knowledge of the condition of his own caliper jaws, correct pressure, fine motor skills and last but not least, regular cleaning.
Thanks, Clive, I've disassembled a couple old calipers, metal and I believe one carbon fiber, as they've ended their lives, and been replaced. I came to similar conclusions without as much solid data, but appreciate your filling in the uncertain blanks. I too, find them incredibly accurate and repeatable, given their price, about 12 dollars for stainless, and five or so for the carbon fiber here in the US. Thanks again, always interesting what you find!
Thank you for this in-depth dive. For a project I'm building, I'm wanting a DRO and digital calipers will serve the purpose well enough. I want to take it a step further, however, in attempting to relocate the 3 axes LCDs / corresponding buttons to a single 3d printed encasement higher up on the machine and, after seeing this video, I'm confident that I can easily accommodate that, even to the extent of tying all 3 on / off functions into a single on / off function that controls all 3 simultaneously. I might even be able to sort out a means to step-down volts / amps from the machine's main power to accommodate elimination of the batteries as well. I really appreciate your video.
I don’t think the device is “tracking” movement. Instead, I think that every position along the range has a unique combination of data, or “waveform” as you put it, coming from the sensors. It simply reads the data and spits out the value for that data reading in any position along the range. Since the sensors are spaced slightly differently than the grid, every position will have a unique “waveform”. Clever but pretty simple really.
I totally agree, and was going to comment the same thing. Every position has a unique readout, just like letters in the alphabet. If you zero at position "F" and you move it to position "K", it will display that you've moved it 5 positions. It doesn't need to recognize every position you move it across (back and forth), bit simply displays the delta distance between the "zero" position and the current position. For this to work, I believe the width of the "finger pattern" has to vary slightly for each "finger". Otherwise, moving it one "finger's width" would read out the same pattern as before.
It's definitely counting all the time, on every movement. I have one, made of steel rather than plastic, which used to be faulty, where it would skip 5mm suddenly once in a while, and the more you run it back and forth, the more error it would accumulate. I repaired it by placing some Kapton tape over the PCB, so it doesn't touch the metal. Had it been sensing in absolute units, it wouldn't accumulate error, the error would clear momentarily. It's also not the case that the short was triggering some button action, because what sensible button action can there be for skipping 5mm in either direction? I think 5mm is just the pitch of the scale. Maybe there's an absolute scale that it reads but it's only 5mm short and repeating, it certainly doesn't have 160+mm of absolute scale. I don't think the reading is entirely continuous, it could be in discrete time steps, but as long as between its readings, you don't move more than 5mm, it's doing OK. Actually maybe should rig up a scope or a logic analyser to it and see. If you even just look at it, at the board beneath the scale sticker, it has a structure that just repeats every... probably exactly 5mm.
yes this is correct, and actually there is nothing to do with waveform, just binary code, each sense pad is read as a binary value and indeed not a single position has exactly the same binary value so we can map directly the resulting binary code and the matching decimal.
@@SianaGearz no, it does not track anything, i explained the principle in another comment. What you saw is correct, but the assumptions you make are wrong, the principle is very simple and on these small caliper the target pattern will wrap after 30cm, which is longer than the physical length. The principle is that each sense pad is interpreted as a bit, and the target pattern is designed so that no bit code will be identical for any given position on the full length, it is the same principle as grey code by the way, the principle used in most encoders. So its just an absolute linear encoder based on some flavour of grey code. On your caliper one (or more) bit (aka sense pad) was stuck, which leaded to an error occuring each 5mm, would have it been another bit the error would be different.
Nice work Clive . It uses interdigital capacitors & a vernier effect . The unused buttons are almost certain to be associated with the SPC ( Statistical Process Control ) port ( Data port ) , used by some manufacturers to monitor production . Keep up the good work !
Besides SPC there are a number of data communication protocols used in calipers. Cables and boxes are available for expensive calipers to connect to a computer but the cheap ones don’t even tell you they are there. They are hidden under unlabeled covers.
Thanks! I actually have one of these for 3D printing. I have a nicer set from Mitotoyo but those are not needed in the house, so I have this cheap set on my desk just to have a reference when designing something. I had pulled them apart on accident and was wondering how to put it back together, found your video and it was helpful!! Fixed the calipers and now can use them again. I need to print a new battery cover though.
If your caliper go crazy and start show random numbers, its worth try to take it apart and clean sliding parts. Mine start working again and I spare some 20€, metallic one.
I have one just like the amazon one, but not plastic caliper...used it very little but on second battery change it wouldn’t work unless I pushed hard with the batt cover off. Then I saw a small sliver of metal on the table. It is the middle piece that makes contact with the plus bottom of button battery. Tried to solder it back in, i possible, so I used copper braid (very thin) solder wick and soldered that in. Can’t put the cover back on but the battery sits so tight it’s no problem. At least got it working again. Very cheap battery contact point.
Incredible how it stays on track even after racking it furiously. this used to be only possible with the expensive ones. Shows that even that tech is simple and cheap to manufacture
the thing is when they start to have trouble its permanent. i used one that never kept its zero. i had to constantly try to clean it and zero it out each day.
@@operator8014 , well if you have a tenth of numbers to keep track of, you may be able to do it ten times faster, right? So it could be that both fast tracking AND double digit precision is still only possible with expensive calipers.
I have one of these. Long-term review here. It's held up pretty good and has been through tons of dogshit. I was 12 when I got mine and am now 20. As mentioned in the video, there's usually no need to go into the precise measurements (there are more precise and better instruments than the verniers). These have been submerged in oil, water, and doused in glue. Swapped the batteries out and got it back onto the bench. It's great value. I cannot recommend this for the professional worshop obviously, but for a hobbyist machinist/engineer, by all means, it's one of the more reliable things China has produced.
For the best part of 48 years I chose after a 5 year apprenticeship to go into heavy engineering even though I was and still am short arsed and never been in double figures in weight, I have a knackered back, shoulder and wrist to prove it . Years ago on a 10 ft vertical borer we only had mechanical verniers, and believe me, using a 6 ft one that weighed a ton and trying to and a achieve a “feel” across that diameter and line up the best line that our eyesight could see, then put a final cut on was at times with a finger up our backside. With the introduction of cmm measuring final inspection we on the shop saw digital verniers. The “feel” we needed wasn't needed, in fact I personally took a measurement, closed the vernier down, and zero the readout 3 times and If I got the same reading that was good enough for me and took the cut, I will add at this point machine tools were getting digital readouts but thats another story. The one big thing with using the digital verniers was that the component would be wet from coolant used for cutting the component and they really did not like that, and all of us had a can of WD40 in our tool chest to combat it. Then they introduced a waterproof version that was 6 times the price !!! These days I work on much smaller components. I have a lathe and other bits and bobs in my garage and have purchased one of these cheap and cheerfull carbon fibre verniers and can only agree with you what a lovely piece of kit they are … thanks for your time …. I love your you tube channel … Take Care
That is actually pretty damned impressive! I figured that cheap calipers like these (I see this type often) would be absolute garbage, but it seems I was wrong, and I am very okay with that!
Lidl/ Aldi did a version of this nearly identical, I’ve had it for years, cost I think about £5.00, use it very regularly and accurate enough for the average home uses :D
I've got the ALDI/Workzone one. Had it for about a decade, and it's still working perfectly. They recently did an updated version, with a circumference option, which is handy, but the build quality isn't as good, in that it is a bit gritty in operation.
@@ConnectMortgages The Aldi one I have is full metal and has two accurate digits behind the decimal point when measuring in millimeters and a kind of thumb wheel with which you can very slowly increase the distance to see the 100th of a digit increments one at a time, if you want to. It did cost 9,99 euros 'though, when I bought it (in 2006), which nowadays is significantly more than 5 British pounds.
@@jiriwichern This cheap plastic one started not measuring accurately last week. I think it's too cheap. The Lidl 'Parkside' metal one still works great!.
The "origin" button on the Mitutoyo ones at work is used when replacing the battery. Unlike the "zero" button, which holds a temporary offset, the "origin" is used to initialise the counter and in effect permanently store the location of zero... until the next battery!
These cheap plastic verniers are brilliant!... I bought several of them to leave dotted in strategic places around my workplace... Plenty accurate enough for a quick measurement 👍
This is the opposite end from the depth gauge. Close the caliper and you will see that the ends of the two parts are flush. These can be used for step measurement.
The encoding used in this is of the absolute type. It's not an incremental count from one end to the other. It actually computes a position value at any given position along the scale based on the capacitive "bits" of the scale. It doesn't matter how fast you move it, it won't lose it's position. Now get the scale slightly wet and it'll lose its position until it dries off.
after having this a while i found the unit kept reseting the value like zero was being push. thanks for taking it apart so i knew what to expect. cleaning all contacts with nail varnish remover and working great again now!
Bolt/screw length. Another minor trick: find screws under decals/stickers by applying finger pressure over the entire surface: screw holes beneath the decal are betrayed by the spherical-section deformation of the decal (think: golf ball dimple), best seen by direct reflection of a broad light source; X-Acto-ing a cross or trefoil inwards from the edge of each hole, through the decal, leaves the decal largely intact, allows for insertion of the driver tip, and retains the screw(s) where needed for later re-assembly. I have a metal vernier of similar lineage. Beyond repair -- cracked wind, missing battery compartment cover, missing buttons, etc. -- and am wondering if the digital gubbins from the plastic variant can be migrated to the metal one -- the advantage of which is the ability to scribe lines on work pieces.
@Gazr Gazr he mentioned the tail hole depth on the small end but most people don't know you can use the top shoulder too. Calipers can measure in 4 locations. OD/ID/depth/shoulder
@@Nate3094 I like to just gently nudge it up and then let it go. If I need to be sure of the exact size, I take 3 or more readings and rezero each time.
at my job i used them all the time. mine had a little wheel as a thumb rest and you could turn the wheel with your thumb to slide the bar precisely. i personally hate the model that dont have the little wheel. its way harder to use them.
@@2000jago try opening the jaws without the wheel, you have to put your thumb way forward and try to grab the unit to drag it open. with the wheel thing, you just wind it up backyard and the module scoot backward.
I always wipe the jaws with my bare fingers and feel for foreign matter, before pinching the jaws with thumb and middle finger, while resetting the zero, with my index finger. It's second nature now!
13:00 Hi Clive. This pattern is the grey code pattern for encoding. This is a grey code linear encoder pattern. Grey code being important as it is an absolute method of measuring position regardless of power loss. :-)
No, it's actually a 7:8 Vernier scale. Human readable Vernier scales are 9:10 ratio, but for obvious binary reasons this scale is based on a power of 2. I almost laughed when I saw Vernier on the listing but I'm impressed that it is actually used. Grey scale is different in that only one bit changes as the number increases or decreases. That's not the case here.
@@StreuB1 I agree, but that is still a Vernier scale. Grey code goes (in binary) 0,1,3 2,6,7,5,4,12,13,15,14,10,11,9,8... Please tell me where you see that pattern. I worked with grey code 40 years ago (and since), it's not something you forget in a hurry.
That handle without the measurement sticker over it looks like a very long but minute stylophone 😅😅 Great vid BG, I take my hat off to you for having so much patience.
Nice to see these actually work as claimed. I'll still take metal ones at twice the price, even though the sensing mechanism is probably identical. I trust that the jaws aren't going to wear down and affect the measurements. Also sometimes what I'm measuring is hot enough to melt plastic, which is manageable with the metal-jawed ones even though the measuring part is cheap plastic. I just have to be quick about it.
The circuit board and the pattern on the caliper body function exactly like the vernier scale on the analog calipers. Put simply: on a millimetre scale, you can't judge if the line is at 0.4 or even 0.35. But having a set of lines that are 1mm less 1/20mm allow you to then see which one of the lines best matches another one on the millimetre scale. The human eye can't see well where exactly between two lines another line falls, but it's VERY good in seeing whether two lines match or not. So then, you read the millimetres off the 0 position of the vernier scale - that would be, say, 3mm and something, then you note that the lines marked 7 and 8 almost match, but the one between them matches perfectly. so that's 0.75mm - the measurement is 3.75mm. The working principle of these electronic ones is exactly the same, only electronic, and it tracks movement instead of position. As you push the slider, the pattern of "fingers" with alternating potential/no potential causes a pattern of 3 electrodes or 4 electrodes sensing to move much faster to and fro - which allows the electronic to determine how far the slider has moved. Based on the maximum length this measures, the number of electrodes and the number of fields, it should be possible to calculate with which resolution and thus precision this works. But I can't be arsed right now.
I was thinking the same thing, have a set of old school Vernier calipers at home as well as my cheap digital set. Best bit you don't need batteries and they are pretty accurate. We also have big 20" and 24" Vernier scale ones at work. The internal measuring faces are ground on the back of the main faces so you allow .400" or .500" depending on the Vernier. All the above have a metric scale on them too.
@@bogdan_n Image 2 sets of callipers Set 1 - Always returns the correct value to 3 decimal places when measuring a known length Set 2 - Returns the correct value +- 1% to 3 decimal places when measuring a known length Set 1 is more accurate than set 2 Both have the same level of precision
@@Bob_Burton Either i'm too dumb, or you don't know how to explain, or a bit of both. But from what you say, i see 2 situations: 1. The first set indicates the correct value (precision class 0) and the second indicates a value within 1% of the true value (precision class 1) So, they don't have the same level of precision. or 2. doing the measurement multiple times. the first set gives the same indication each and every time, while the second set gives different indications, varying within a 1% window. In this case we are talking about the repeatability (or, in some languages, the fidelity) of the instrument. Or it's just a language barrier, as in my language we have the "precise" and "accurate" terms, but they are synonyms.
@@bogdan_n They both have the same level of precision, ie 3 decimal places, but one is more accurate than the other, ie one shows the proper measurement and the other doesn't Suppose the second one always gives a result 1% too high instead of giving variable results. Does that help understand the difference ?
@@bogdan_n One is how close you are to the actual value (accuracy). The other is consistent you're getting the value (precision). A great visual is target shooting. -hits are all over the place, but your average is dead on. Poor precision, good accuracy. -hits are all over the place, but the grouping is also way off the bullseye. Poor precision and accuracy. -tight grouping, but nowhere close to the bullseye. Precise, but poor accuracy. -tight grouping and right on the bullseye. Great precision and accuracy.
Thanks Clive! You saved me after I carelessly took apart my 12" (300mm) digital calipers and didn't note where all the pieces came from as they just fell out after I took out the screws in the wrong order. Although mine were a bit different, I was able to learn enough to reassemble (after repairing a solder joint on the + contact) and it's now working again! :-)
another completely pointless video for ad revenue
Sorry. This channel is aimed at technical people.
I found it interesting, if you do not then that is your decision.
Its not the video thats pointless, you just dont know shit, you brag about intelligence and knowledge in every of your comments, but you dont have both
Kind of weird mate
I mean he has a channel talking about tech products, what do you want him to upload lol... seems like someones jealous...
I suspect that most things in your life are pointless @Shawn/IO.
Have you thought of asking your parents why you were named after a Sheep 😂🤣😃
I deal with the lack of a hold function by just pressing zero, and closing it again. Then it shows the negative of what the measurement was.
Good idea.
I have that caliper as well and do the exact same, works great for me
Works pretty damn well aha
Good tip thanks👍
Oh God! I have just discovered I'm an idiot. Thank you for your help, Sylvia :)
Has a screwdriver with a changable tip. Has more than one to avoid changing the tip...
NGL, I have the same type of thing going on. I have multiple workbenches, and there's a pair of sidecutters at every one. Electronics, casting, 3d printing. I kept always having them at the wrong bench no matter which one I was using until I bought a pair for each lol
:BigClive logic
It's what people who actually use their tools do.
Well.. if you only need 2-3 bits for a job it does make sense that you don't want to constantly change the bits.
And it still lets you be versatile for many jobs where different combinations of those 2-3 bits are required for each one.
Also. If I recall correctly. The whole point of replaceable bits was to keep costs down in factories where robots and human workers could toil away using the same type of bit endlessly. Endlessly replacing that bit with a new cheap one as they wore out instead of a big new and comparatively expensive screwdriver each time.
So it does make sense in multiple ways to have multiple bit-holders. :)
@@OfficialNukeDukem It was definitely a moment of recognition for me. :P
After 10 years mine gave up and didn't switch on anymore. I purchased another one from ebay- a metal one. What arrived was trash. Astonishingly, I was able to transfer the display, pcb and housing to the old chassis. Everything was the same. I'm astonished the parts we're interchangeable. Thanks Clive for giving me the confidence to even attempt the fix rather than send both to the bin
It's pretty crazy how compatible many Chinese devices are, due to the absurd amount of corporate espionage and clones of older products.
@@albertweber1617 thats the meaning of efficiency;)
I worked for a company for a a number of months repairing precision measuring equipment including calipers, depth gauges, height gauges, micrometers, you name it. Mostly mechanical, but also electronic versions.
What you were able to surmise and figure out from what you saw, without knowing the sorts of things I was taught during training, is amazingly accurate.
The main problem with those digicals is once they go wonky, there is no currently available way to repair them.
With the analog ones you can always regrind, retension, rerack and realign, but the digital ones go in the recycle bin.
Interesting. Can you tell us more about how the Vernier gets read in these?
Mine was £7 summat from Aldi, so just chuck em if they go faulty
@@johnf3326 I ordered one two weeks ago from Aliexpress for 2,5€ free shipping XD
@@spicesmuggler2452 i got one from Aldi for 4,99€ and one from Aliexpress for 1,89€ with shipping.
@@johnf3326 it the 2 PCB'S that are the important bit, and there going to be made by a third party, PBCway springs to mind, but there more company that make PCB's and by the nature of the device, any take making that part, will have have high tolerances, and thing PCB's just have the stable don move shape much if at all unless being cooked, and the finished machine is self calibrating anyway knowing what it's own moray field pattern, as the two parts move?
would be intresting see fails where manufactured, to the number fully working ones, not including one build as lemons?
I've often wondered how they made these things and managed to make them so cheaply yet with an incredible degree of accuracy. Thanks for making this interesting video.
this might be okay for home use, but for more applied uses, you might want to get something with a bit more resilience. i can't see that thing lasting too long for someone operating a lathe.
@@eatmywords yes totally agree. I've got a set that are better than the ones in the video but still cheap. It's only for DIY use but I wouldn't use something like that for serious and everyday use.
@@eatmywords Yeah, clearly, if you're doing lathe (or any kind of workshop tools) work, you won't be using 5 dollar calipers from Amazon. That would be like putting Walmart tires on a supercar. But while my calipers at home are a tiny bit better, going down to hundreds of a mm instead of just a tenth, it's still a pretty cheap one, and works perfectly well for anything to do with 3D printing (printers don't really get much accuracy beyond a tenth of a mm anyways), or any other random things I happen to come across and need to measure
I might have to eat my words and buy a better one soon tho, now that I've bought a cnc machine. But I don't really have any plans on using the cnc for anything super critically accurate anways.. for now
@@Excludos i've used 20€ catapilar for my years in CAD school (i'm not sure howto translate it to English but basically, i mesure sizing of part for a broken machine, and then i just create it with a fraiseuse Tourneuse) and it was actually quite good compared to my prof high end thingy, as long as you never drop it, it's fiiiiine
Would have been better if he'd looked up Vernier scale on Wikipedia. That's what's really going on at 12:28. Before electronics, it was purely a visual aid, and it's fascinating how it works. It's the reason I don't bother with the electronic ones. Yes it takes a little more mental effort, but it's a mental effort that I find quite enjoyable simply because it's so fascinating.
I looked into this technology a while back. Essentially what you have is a capacitive linear position sensor. It's not a vernier. The principal is that the teeth of the narrow comb on the sliding PCB are excited by the chip using sine waves. These teeth are in interleaved groups, and each group is fed a sine wave at a different phase. These teeth capacitively couple with the large comb on the measurement rule, which in turn capacitively couples back to the single long receiver bar back on the sliding PCB. The result is that the output from this bar is another sine wave, and critically the phase of this sine wave is determined by the position of the fine teeth relative to the large teeth. So a full 360˚ of phase corresponds with the pitch of the large teeth, 0.2 inch in this case. The chip measures this phase shift to determine the position relative to the set zero. So a 18˚ shift corresponds with 0.01 inch for example.
In fact in these cheap calipers it's all done digitally. The excitation is done using PWM coded sine waves, and in the example here they're fed in differential pairs, so that's 8 signals, four pairs, 45˚ apart. The output is then very spiky, but with a sine wave envelope which is recovered by digital filtering. Somebody scoped this version a few years ago - see web.archive.org/web/20120328090506if_/www.yadro.de/pics/hp-logic-analizer.jpg. You can see the four PWM sine wave differential pairs in the 8 digital traces at the bottom, and the single output signal before filtering at the top. Just imagine the peaks of the envelope of this signal are 0.1 inches apart and the signal shifting across with the slider and you've got the idea.
The reason for 56 small teeth rather than just 8 is to multiply capacitance and therefore multiply the signal output, plus averaging of any small physical inaccuracies in and impurities around the teeth. So each set of 8 small teeth in fact precisely line up with each pair of large teeth.
How does the absolute encoding feature work? How does A high-end Mitutoyo know its position immediately upon waking?
@@huntma3787 I have these same inexpensive calipers and they remember where they are when you turn it on too. Since it has a move to wake, as soon as you move it and since it has the last position stored it knows where it was / is. Now whether the Mitutoyo is really absolute or just does the same function, I don't know. I would tend to think it's the same as these. Now, if you took out the battery, moved it and then re-installed the battery and turned it on, that would tell you for sure if it is absolute or just storing it's last known position. But good question!
@@huntma3787 as long as they have a battery the cheap calipers never fully turn off....
all they do is turn of the display. so they are essentially always keeping track on where they are. other than that they are purely relative. though amazingly quick as demonstrated when they didnt miss a pulse during the rapid movement.
but that also means that they eat batteries like crazy.
@@TheScarvig A Mitutoyo (if you get an authentic one, not an eBay counterfeit) doesn't eat batteries the way the $10 calipers do. It can go for years on one battery. I assume it has a small flash memory component that the cheapo models don't have.
@@jpdemer5 the issue isn't storing the last value...
the MC inside must be active to read the capacitive encoding to detect the movement and wake up the display automatically.
if it only wakes up from a button press then its easy to send it to deep sleep, but then you wont keep track of the position while its off.
they could tie the wake up to some other passive component that reacts to the movement of the jaws, but then still the MC must wake up quick enough to not loose any increments on the scale.
so thats an awful lot of engineering for an, imho, pretty useless feature...
just zero the damn thing after turning it on!
When these calipers came up we tested them with some small drops of water under the slider to see that they work with capacitive sensors. The instrument was in fact confused. After little drops had dried out it worked normal again.
Mine got wet and I had to wash it out and let it dry.
Was completely goofy until it dried, as good as ever once dry. I prefer the older ones from Harbor Freight (in the US), but the new ones are all plastic, sadly.
Tough too - I have dropped it a number of times.
I use the original visual Vernier scale only, as they existed before electronics. I never have to worry about liquids (except the kind that could etch the Vernier away ;)
@@TesserId you also need to worry tremendously about the mechanical characteristics of the metal the scale was printed on, whereas electronic ones (especially the advanced models from trusted brands) don't. Everything is a balancing act which depends solely on your use case.
When I saw Ave review one of these cheap calipers a couple of years ago, he almost made me feel ashamed of myself for owning one.
You've restored my self esteem and confidence. Thanks Clive. Keep your beard in a vise.
This cheap plastic one seems more accurate than my cheap steel ones from Harbor Freight. They never seem to go back to 0 reliably.
@@bigpjohnson Although this super simple design probably doesn't allow it, cheap designs resort to trickery. For example, my cheap bathroom scale remembers past measurements to give fake consistency. It's probably only accurate to five pounds, I mean I can literally grab a weight and it will claim I weigh the same, to the tenth of a pound.
@MichaelKingsfordGray what ?
Cheap calipers are good for some things but they can be a major major waste of time. Really you should own a beater pair and a good pair from Mitutoyo or similar. There are places you won't want to stick the Mitutoyos but they are a decent source of truth. Also a caliper that only reads tenths of a mm is probably not something I would trust even for 3D printing. Really you want an extra decimal place of precision past the accuracy you're aiming for.
The ending bit where you moved it as fast as possible to prove it wasn't a relative measurement has convinced me to buy one of these. The plastic, even on good models, always felt like cheap junk to me and I was sure there's no way it's actually as accurate as it wants you to believe.
"I wonder if this pops off". I've found that with (in)appropriate amounts of force and leverage anything will "pop off". The tricky part is getting it to pop back on again. : )
If brute force isn’t working, you aren’t using enough of it.
A tire storage place managed to hire someone who fit this perfectly
On his second day, the local newspapers told the story of how he had succesfully removed all 4 rims..... Without removing the lug bolts....
My version - "I wonder if this pops off" *snap* "Oh yes, just once!"
yes russian tank turrets pop of really well when an NLAW or JAVELIN is applied
So the capacitive fingers do work exactly like a traditional vernier scale, with the wave of lined up fingers moving across then restarting at the beginning again.
Yeah, that's pretty much how it works.
That was my first thought, when I saw how the marks went in phase. Just like a vernier scale.
Yup, great for people who's eyes can't deal with Vernier scales any more.... Or so I'm told ;-)
Indeed. I always thought these things were wrong to call themselves 'vernier' calipers because they're not read via a Vernier scale like the typical non-electronic ones... but it turns out they do still use the Vernier scale principle behind the scenes. Nice!
Having taken apart for repair/cleaning more than a few mitatoyu
I'm sitting here, with my jaw hanging open, laughing at how accurate these things are even after taking it apart and jamming it back together. I bought a metal one a while back, for €7 at a store called Action (in NL). It has pretty much the exact same display, buttons and battery holder cap, but in silver/grey. I'm just amazed now I learned how they work, I always thought it would be like a little scroll wheel inside, but didn't expect it to work contactless. Amazing!
"Carbon Fibre" or black plastic with random grit included, possibly soot (carbon) and grain dust (fibre).
To be fair, raw carbon fiber is DIRT cheap, really not an expensive material at all.
Probably glass filled nylon. Perhaps.
I've actually got one of these lol. I scratched it up a bit, it does have fiberglass in it. Still no idea what they marketed is having carbon fibre, these things cost like 10 USD...
Carbon black pigment if you want to be generous, it's not like marketing needs any grounding in reality!
There’s GFRP (glass fiber reinforced polymer), which is relatively commonly seen nowadays in high strength applications. There’s also CFRP, which is basically the same as GFRP except it swaps carbon fibers for the glass fibers.
It’s not the woven carbon fiber stuff people think of when they hear “carbon fiber”, but it’s still carbon fiber
It's worth keeping in mind that the flex in these calipers means that it's difficult to measure beyond .1mm without influencing the measurement just by the amount of pressure being put on the caliper.
More advanced calipers and micrometers have a wheel or knob with a clutch to close the jaws on the part being measured. The clutch is adjusted so the user can't apply more than a certain amount of force before it starts to slip. That way the pressure in the jaws is always the same, and the measurements are consistent. I have a $20 electronic caliper from Harbor Freight that has a wheel like that.
Agreed - repeatability and accuracy of finger pressure is pretty unreliable. I file small components to sub thou" accuracy so this particular instrument is not for me. For about three or four times the price, the stainless option is still great value and serves me well. They also have a variant that can be switched to display fractions of an inch - great for old fossils like me ;
@@bigoldgrizzly To be honest, if you need it down to the thou you'd just use a micrometer. There's a type for every sort of measurement.
@@233kosta quite so in most cases, These work well for me for small internal measurements, as well as external. Fitting steel reeds into slots with about half a thou clearance. Handy to be able to do both with the same instrument.
In case you are wondering, I make new reeds for concertinas. Just to make it more fiddly, some of these are also tapered both in thickness and width, along their length.
What I was told during my apprenticeship at a machining shop was that calipers are only accurate to 0.1 mm for measuring, but you can use the added digit (on professional calipers) to see about where you are with regards to the measurement. What it means is that if you had to measure something to 10.5 mm +- 0.02 mm you could not use the calipers to do that, you'd have to use the micrometers.
The true accuracy and precision of a caliper should be stated in the user manual.
A buddy of mine used one of these to make an RDO for his drill press. The serial interface on these is the real secret gem. There are so many potential applications for it.
So those four pins are UART?
@@kaikart123 I came across a page with the hack and protocol, but since I had no interest in it, I didn't bookmark it.
That was over 10 years ago. So, I imagine they know even more by now.
@@piconano I got you, fam sites.google.com/site/marthalprojects/home/arduino/arduino-reads-digital-caliper
@@kaikart123 The pins just send a constant stream of bits, using the BCD protocol, widely used and hacked.
I have bought a few of these, only to find out the serial output does nothing on them. Not a peep, not even with added pullup resistors. So beware of that. The PCBs look exactly identical to these.
2:26 You can use the back of the head to measure distances too. Works kinda like the depth gauge, but the larger flatter surface can be useful to keep your measurement square.
I was about to type the same thing. I saw Abom79 doing that years ago on his channel, and I use that feature all the time now for measuring offsets.
Lots of people miss this very handy fact.
Which part are you calling the back of the head?
@@JasperJanssen You can see what I mean @ 18:06
I always forget about this and end up using the depth gauge on the other end which can be a bit clumsy depending on what's being measured.
I would love to see the differences in the 0.1mm precision calipers and the 0.01mm precision version. I'm curious if it's just more lines on the respective pieces or if it's done inside the processor itself.
I'd assume it's both. Like considering the actual sizes involved on two paralel surfaces i'd say they use differwnt tech process to make pcb more accurate, like using different photoresist(the better the "resolution" at which it can "harden" the costier it gets), different mask tech(i don't even know what they do it with in high end machinery, maybe some fancy pants uv projectors with complicated optical system), better, more accurate enclosures, etc
As user of the old visual Verniers (never bothered with electronic ones), it's pretty obvious that it would either have to be an order of magnitude smaller or an order of magnitude more lines. If it were to turn out that they were the same (which they might well be), is one rounding for a cheap display, or is the other algorithmically advantaged? With a computer science degree, I'm trying to imagine what that would entail.
Ah right! Was wondering why anyone would reinvent the 'wheel' (processor) when they have existed off the shelf for 20 years and are likely now dirt cheap .. makes sense that the cost would have been cut in the encoder resolution/accuracy, and so overall assembly.
@@JimTheZombieHunter We've pulled apart both 0.1 mm increment plastic (carbon fiber) units and 0.01 mm increment metal units. They appear virtually the same inside. The difference is in the display, in that the plastic unit doesn't have the extra digit. Presumably because the plastic one would not have the repeatability of the metal caliper. Maybe they are more precise in manufacturing the pads of the unit with higher resolution.
@@TesserId I _don't think_ that would actually be necessary. Additional precision and/or more lines of some sort may be required (though maybe not; they may just not display the extra digit on these, but be capable of calculating it), but even if so... well, I'm not sure, but I suspect there could be tricks done by having just different offsets on some of the things.
I would imagine that, being that the wavelength of the sliding part is variable, that they are effectively self-calibrating, because moving them will emit a certain wavepattern at a certain place which the chip can then corrolate to a position along the length, even if you thrash it really fast as soon as it moves it knows exactly where it is. Also, reading if the waveform is lengthening or shortening will tell it what direction it's moving in with no other moving parts. Bloody genius.
I use digital calipers at work every day and I appreciate the amount of time I save compared to reading non electrical ones. Instant numbers showing up is such a time saver
Thank you for this video. And it is indeed amazing to see how a cheap construction can still deliver an accurate measuring instrument.
We would say it is "precise" because it has more digits. Accuracy has to do with the correct number being displayed.
That's right, more digits means you can be precisely wrong.
FWIW, I have a Mitutoyo calipers (about $175), plus several mechanical micrometers (one of them a Mitutoyo as well) and a digital mic that goes to half a tenth, plus about 4 Harbor Freight digital calipers. I've never found any inaccuracy between them. All four of the $20 HF calipers measure my inch standard at 1.000 inches, same as the mics and the Mitu. So I think the accuracy is there as well as the precision.
Yes. π=3 is accurate but not precise. π=7.47962974741 is very precise but not accurate.
Resolution is what he meant
He eventually does get to the point that it is both accurate and precise. Win!
If you get a set I'd recommend storing them with the battery removed. And keep a spare battery with them. :-)
I've been there.
I got tired of replacing batteries every time they sit idle, so I just ponied up for a few pairs of Mitutoyo calipers...now I replace batteries after YEARS...not WEEKS.
Neat. My $10 set has a solar panel to charge the battery. I left it for a while in a box and indeed the battery had died. As soon as I went outside it turned on.
Could not agree more
I've some of these that are coming up to 3 years old and are still using the supplied battery. I've also got one that will eat the batteries quicker than pacman. Chinese lottery.
@@RK-kn1ud Mitutoyo Solar Digimatic, at least there are no counterfeits.
now only if there was a way to feed that data of a control board for feedback of CNC as most low end board does not have leaner encoder feedback but if it was there then all low end CNC (small PCB mill , 3D printer , Engreaver & Laser cutter )would become super accurate
ua-cam.com/video/8TAvbxLuBEU/v-deo.html
I am not an expert but I think the challenge with PCB mills and 3D printers is frame rigidity more so than inaccurate stepper motors.
@@sourcefollower It doesn't matter how rigid the frame is if the X,Y and Z axis screws aren't accurate enough in their pitch to produce a resolution of at least .02 mm.
There are many other factors that apply more than a rigid frame, like squareness of the axes and backlash in the screws.
@@gangleweed If the CNC machine was using scales along each axis to position itself, it wouldn't need to rely on counting turns on a lead screw. Move 6mm, would be move X position on scale - not turn (6mm/thread pitch) rotations.
@@52Ford It's always been done with an accurate ball screw....why change what has always been reliable and simple.
The mechanical bits are important too. Straightness, parallelism, rigidity, stiffness, etc. They also have an impact depending on what is being measured. Having a locking screw and being able to use the sharp metal tips of the interior width gauge to transfer point to point measurements can be really useful. Thanks for the video!
Definitely worth the extra fiver to get a metal set in lidl or wherever
Love how you checked those extra button positions for us. Again, BigClive goes above and beyond for his Patreons.
I was just typing a comment at the end of the video suggesting that he should have done so, and then realized that he was doing it as I was typing! lol
Why didn't he hook up a scope on the data channel? And analog output to get the sampling frequency!
I have the exact same calipers and they're totally adequate for my needs. However here's two tips;
1) Remove the battery when it's stored, otherwise it may go flat. This may be due to carrying them in my car. The jolts may be switching it on too many times.
2) If it starts to read just half of the true measurement, just remove and replace the battery. Reboot!
Thanks Clive, that was very informative.
The batteries just go flat because there is no true power switch so there is always a small parasitic loss as the circuitry inside constantly monitors for the pressing of a switch. It's the same with all sorts of devices, like remote controls which do, of course, have much more batery capacity. I too remove the button batteries from these type of devices when I put them away.
Thank you for number 2.
Just thought you would like this random bit of info, these are used to measure the thickness of the biscuits made at a factory I did a job at recently.
I guess that makes sense for uniform packaging and weight.
:) I find the use of a pair of precision calipers to measure cookies hilarious, but it's even funnier in America, our biscuits being big soft, squishy fluffy irregularly shaped flaky things.
@@tedhaubrich This particular biscuit company had imported a machine from italy to make the biscuit dough to relieve the poor lad who hand made it every day. The machine was a giant and cost £100,000 or so. It couldn't make a flat piece of biscuit dough. I told them it wasn't a surprise as it was a machine designed for making pasta.
We measure the thickness of biscuits with our teeth.
I love biscuits and I love precision.... Precision biscuits?....Wow, mind blown 🤯
Very interesting. I use mine all the time and was always amazed at how repeatable (and probably accurate) the measurements were. Thanks for explaining how it works!
... I never thought or be dared tacking mine apart I would brake it and could never put the thing back together ... but it's nice seeing what's in side 😂😝 ...
Explanation of how it can read so precisely while using so few contacts: being advertised as a Vernier caliper, it is most likely using an electronic version of a Vernier scale.
Vernier scales work by using a main scale for a larger unit, and then a smaller scale for a subdivision of that unit. the smaller scale is divided into lengths equal to the main unit minus the subdivision, so if youre between ticks on the main scale, each tick along will bring the ticks of the two scales more closely into alignment by precisely one subunit. this means you can find the scale's reading by counting along the smaller scale from the main unit you measured until you find the point at which the two scales align, and add the corresponding number of subunits.
It's easy to see how the circuitry displayed would be able to achieve this, and also explains the slight mismatch in length between the groups of contacts on the circuit board and the capacitive strips on the body.
That's what I thought as soon as the two scales were aligned. The circuit contacts are physically the same as mechanical Vernier callipers. I see no need for any complex 'waveform' or binary encoding of all of the elements. I don't have anywhere near the knowledge of electronics as 'BigClive', but it is basically a mechanical device with a digital output instead of a physical one.
I have watched other videos of his as I have the same scientific curiosity about almost anything.
When I saw it advertised as Vernier calipers I thought they were just misrepresenting the product. But when he opened it up and I saw the pattern, I assumed it was some kind of electronic version.
I bought a cheap steel digital calipers years ago after buying my first 3D printer. It's since been probably my most used tool. I love em!
It's cool seeing how these take and record these measurements and it hurts my brain to think about the calculations required to interpret the signals coming from that capacitor array thing.
That skewed capacitor array works exactly like the vernier scale on traditional calipers. Detecting which line matches up gives the least significant digit, while counting the large marks passed gives the first digits. Write the two halves after each other, then apply the inch/mm unit conversion. Of cause, having 8 measuring channels suggests the use of binary digits instead of decimal ones.
This was like watching one of those nature documentaries where you see a baby bird being eyed up by lizards - you're so sure it's going to get eaten. There's no chance it could survive.... is there?
If you see and work out how a metal manual vernier works ...im sure you will see how the electronics and circuits look similar
There is a fourth measurement you can take with calipers like that that most people don't realize. Aside from the tail, you can also use the opposite end. Since the two parts are flush at the "Left" end, you can measure a step.
As a mechanical inspector on a UK military aircraft project, who uses Vernier callipers on a regular basis (not ones supplied by Lidl may I quickly add). This strip down has been so interesting and enlightening about an item of measuring equipment I've taken for granted for so long and often wondered how they actually do work. Thank you so much.
Re the very last bit: it’s actually not just tracking it at jphigh speed - the capacitive vernier system provides an absolute position, rather than relative. Or at least, it’s absolute within the repetition horizon, which is probably something like 30 cm. If they get super long, you might be able to get a situation where it’s off by , but never by a small amount.
Im pretty sure you're wrong there.
That's a simple capacitive interference sensor with a repeating pattern. It's definitely a relative position sensor and needs to be set to zero by the user at some position.
The reason it doesn't lose track of position is because the sample rate is faster than the speed you can move it, quite trivial these days with very high speed MCUs and the pattern repeat being large, about 20mm long.
(Edit) sorry it's 20mm long for half a phase so maybe 40mm long for a full phase.
@@wizrom3046 sounds like we need a follow up video.
Just got myself a cheap digital calipers today. Same type. Perfect for my level of hobby and need so far.
Just a FYI, these “cheap” callipers don’t turn off completely. The encoder is constantly drawing power to remember its last position, allowing it to turn on when it’s moved.
Subsequently, the battery dies fairly quickly when the device is left with it in... I’ve started to store mine with the battery removed.
@@rushilkisoon Indeed, spent about twice as much to have a mechanical one (which turns out to be more accurate AND precise, bonus), because the empty batteries annoyed me fast.
I got a expensive metal type for more accurate measuring and this cheaper digital one for simple parts.
Quite weird but I got it for like 2 years now and the battery is still good 🤔 never take it out when I store it.
looks like a Vernier scale system is being used
I agree - a digitised vernier. It looks very much like my old fashioned 'battery-free' vernier calliper!
@@mrclucker1969 exactly what it is. @bigclivedotcom if you look here you can see the original analogue explained. ua-cam.com/video/rdFwZaRgO8s/v-deo.html
I agree. By making the spacings between the moving strip and the spacing on the ckt board different, they are able to generate a 'pulse' much more often than what can be practically printed on the PCB. I'm sure the PCB manufacturing can't space close enough together for the accuracy desired, so they used this variation of Vernier scaling to increase the resolution of the pulses.
@@mikefochtman7164 that's my conclusion as well. It's amazing how much resolution it has for the cost of the materials and manufacturing.
I've been using one of the slightly-better-but-cheap ones that go to hundredths of a millimeter. Always wondered how they work, thanks for taking the time to take those apart! I've found that hundredths of a millimeter are really useful (almost mandatory) in 3d printing since filament widths can vary by brand, anywhere from 1.6 to 1.8 mm. being able to tell 1.72 mm filament from 1.78 will often make or break a print since the volume of plastic being extruded is dependent on filament width. Also getting that first layer to come in at exactly .15 mm (or whatever you're printing at) is also really important.
Have the same and works great. This technique could be used for digital (and motorized) potentiometers for audio mixers. The zero function can be used to set a memory location to be able to move to exactly to the same position. When motorized, it can be used to fade-in to exactly the same position. Very clever design, love it. Thank you for showing us.
The clue is in the phrase "vernier scale" which is, according to Wikipedia, "a visual aid to take an accurate measurement reading between two graduation markings on a linear scale by using mechanical interpolation; thereby increasing resolution and reducing measurement uncertainty by using vernier acuity to reduce human estimation error": "The vernier is a subsidiary scale replacing a single measured-value pointer, and has for instance ten divisions equal in distance to nine divisions on the main scale. The interpolated reading is obtained by observing which of the vernier scale graduations is co-incident with a graduation on the main scale, which is easier to perceive than visual estimation between two points."
en.wikipedia.org/wiki/Vernier_scale
I spent a lot of time reading verniers in my first year at university. I haven't done it since, but I remember the principles. I had never imagined an electronic vernier, but here one is, and what a good idea!
Yup. I have a small vernier ruler, with the pocket clip slider.
@@zh84 The electronic ones aren't Verniers at all, although you might think so from looking at the circuit board. They rely on an AC signal that changes phase as you move the slide.
12:28 ...so it really _is_ a vernier caliper, just that the vernier scale is implemented by the fingers on the circuit boards?
That's what I was thinking. The small contacts on the pcb correspond to the small scale on a vernier that gives the fractional measurement. Quite clever.
I would think so, but each 8th small contact is connected in parallel. So there's effectively only 8 small contacts that cover only 2 big plates on the other detail. This means that there're at most 2 small contacts that are located over the border between big plates and can sense anything meaningful. Seems not sufficient for required accuracy at the first glance. It's also not clear why to repeat this circuit so many times and connect all on parallel.
8:24 : The mystery button next to the inch/mm one used to allow you (in the inch mode) to switch between decimal and fractional values e.g. 1.500 → 1½
the missing button on the OFF/ON and ZERO buttons row used to be HOLD.
I watched this video over a year ago but came back after measuring a soapy part of my shower. The read measurements went haywire: 0 was 0 but 20mm was 80 something and then 30 was 40 etc. it just bounced around! I thought of this video and realized the contacts must be contaminated. A quick tear-down and wipe with an alcohol pad and then re-re-watching this vid very close to understand where the pieces went - thanks Clive you saved me a few days without a micrometer and $9!!
I have the exact same caliper and am very impressed with it, after pressing zero and then pulling all the way back and also reading 1563mm. I use it mainly for my electric bike conversion project while also adding mudguards and other accessories that need them to accurately measure fiddly nuts and bolts washers without the guesswork and are easier to read than the manual steel version which is difficult to read after time and tarnish.
Bought one almost identical 2 years ago as to test out. It's still works and hasn't failed me.
Harbor Freight? $9.99 today :)
6:18 - secret stylophone unlocked!
i can hear the metallica songs now
Stylophone? 🤔
Not kidding - As I read this I heard the Legend of Zelda "Hey you got some new shit" sound :D ... I dont even know why it was subcontious.
@@JesseCombsTwiZtedCheese ua-cam.com/video/cF5JedknFGU/v-deo.html
Yup, Rolf Harris uses one to measure Kangaroo dicks
It is uncanny seeing the exact same calipers I bought a while ago being torn down by The Big Clive.
Same here. Guess all the companies are buying from the same factory
Exact same here haha
Got mine from ebay for measuring 3d prints, though it only reads up to 155.3mm instead of 156.3mmm :-)
What if they are your calipers? You never know when some random UA-camr may pay a visit to your home during your sleep.
@@peterrockell1527 so who nicked the other milimeter?
The clever thing of these is that they don't track the movement. They just read the position they are currently at. That enables them to still show correct values after moving the up and down at light speed haha :D Great video!
The one I have is a Pittsburgh 'brand' from Hazard Fraught I picked up in the states for $12.99. The meter part is virtually identical (including buttons, battery compartment and screw locations) except it sports a metal thumbscrew in the side that's meant to serve as the 'hold' and has a metal thumbwheel next to the plastic thumb grip. The rest of the unit is steel instead of plastic. Great little tool for the price.
"Lets take it to bits." Would make a great T-shirt.
mug, tote bag, fridge magnet, computer sticker,
... band roadie jacket!!
"Let's take it to bits. One moment, please..."
'I shall pause'
The hammer of knowledge ;)
One moment please. For me :)
Thanks to the data port (which is a premium feature in 'real' micrometers), one could build a super cheap super high accuracy linear actuator servo!
I bought BOTH these exact same models from China as soon as they became available. At that time I guessed they use the usual principle of vernier gauges, resolved via capacitance measurement - as Clive has now revealed. They are amazingly good value for money - especially when your eyesight is beginning to fail and steel rules and vernier calipers are becoming more difficult to read!
Thanks a million for this video. I'd taken mine out of a drawer for an upcoming customer visit next week, and left the calipers on my desk. My seven year old picked them up this evening, waving them around like a sword stabbing things in my office and somehow broke them into pieces. I watched your video and was able to reassemble them in a few minutes. They still work great and now my sword is fully functional again. Thank you!
Only one thing to mention, it will not work without energy. That's why I rather like the classic industry ones.
Great job thanks for the footage.
I held onto my first-bought 1/20th mm vernier caliper for more than fifty years now, and counting. Still works great, and I never need to worry about the battery being exhausted.
Best tool ever. I have the 8"/200mm version and it measures down to 0.01mm/0.001". Sometimes I just wander round the house measuring random items because I can.
I keep an extra set next to my chair where I watch tv. It’s amazing how often I am fiddling with some gadget or idea and end up using them. I have one in the basement workshop, one in the upstairs craft room, and one in the family/tv room.
hahahaha, same here!
So I have a somewhat more expensive steel version of this that goes down to hundredths of millimetres, but the black plastic bit with the screen is absolutely identical to this one! I was always really surprised about how accurate is seemed to be, glad I know how it works now.
I wanna see an Oscilloscope on it, this teardown was very interesting and I'm really intrigued now to see the waveform on those fingers to get a better understanding of how it works.
Is the software comparing the phase angles and timing coming back from the fingers?
I think it is just a Vernier. the chip keeps track of number of steps passing by, and then uses the vernier magnification; the strongest signal, or is it lowest capacitance, is where the best line-up is?
Yeah, I'd love to see a scope on this, too. Maybe this is where we ship it off to Dave for a whiteboard treatment, too? :)
(Not that Clive wouldn't be capable of that, I just imagine he'd get bored, because it wouldn't be destructive enough. ;) ;) )
I bought an "all metal" digital caliper over 20 years ago for about US$10-$15 and it's still working fine and with no "slippage" requiring periodic resets. With excellent accuracy and especially repeatability it's been an excellent tool.
It was just a no name "Electronic Digital Caliper" that I got from Circuit Specialists. Even the plastic box with formed foam cut-out for the tool is still 100% serviceable. No sign of hinge deterioration. Some things just pleasantly surprise you.
Brilliant - saved me taking one apart to see what was inside
I got one of these about a month ago. I'd love to see the output of this on an oscilloscope.
These use the BCD protocol, it's widely researched and hacked. Google 'Caliper DRO' and you'll find plenty of posts on this.
This is great, I've always wondered how these work.
Yeah saves me from tearing mine apart
I think one of the missing button and the missing part could be a single led and button for lighting up the screen
Oddly, I have just bought a very similar model from Amazon (the ‘ruler’ part is completely identical), but the three buttons are along the bottom - it was a toss up between them being above and below or just below, I went for the cheapest. My thoughts as I was watching this was a manufacturer churning out these with a few slightly alternative cases so companies rebadging/ branding them could appear like their offering is different. It’s certainly not so uncommon in electronics these days.
Writing that thought down though, I wonder - considering all the unused connections - if the board is even more generic and gets used for other related devices, we can argue plastic over metal, but is a metal version necessarily (electronically) any different? Even the level of accuracy could be down to the software an otherwise identical board is flashed with.. it wouldn’t be the first time the cheap and the premium model turn out to be the same thing under the hood, and the array of choice actually leads back to a single manufacturer carefully differentiating one product.
I am impressed that you were able to dis- and reassemble this without once (except when quoting the eBay title) uttering the word "vernier"!
I am in Electronics hobbyst and I have been using one of these since 2008, it is doing its job just fine which is satisfactory for me.
23:14 - Well, that's the first time I've seen anyone openly do that particular action with their tool on youtube........... :P
@David Firth Size matters.
FYI, if you want to set an origin, you can just zero it at the point you want to set that. Works the same way.
A hold function could maybe be used to add up different measurements.
Remember though, just because something displays to more decimal places, doesn't mean it's accurate...
Indeed. Never confuse resolution with accuracy.
I've had metal digital calipers that had 0.01mm resolution, and the jaws to measure ID where off by about 0.5mm. Same for depth guage
even the expensive ones are inaccurate
Right you are! The number of decimal places relates to precision, not accuracy. An instrument may be precise but not accurate. Conversely, it may be accurate but not very precise.
It is repeatable. To obtain accurate measurements one has to have intimate knowledge of the condition of his own caliper jaws, correct pressure, fine motor skills and last but not least, regular cleaning.
Thanks, Clive, I've disassembled a couple old calipers, metal and I believe one carbon fiber, as they've ended their lives, and been replaced. I came to similar conclusions without as much solid data, but appreciate your filling in the uncertain blanks. I too, find them incredibly accurate and repeatable, given their price, about 12 dollars for stainless, and five or so for the carbon fiber here in the US. Thanks again, always interesting what you find!
Thank you for this in-depth dive. For a project I'm building, I'm wanting a DRO and digital calipers will serve the purpose well enough. I want to take it a step further, however, in attempting to relocate the 3 axes LCDs / corresponding buttons to a single 3d printed encasement higher up on the machine and, after seeing this video, I'm confident that I can easily accommodate that, even to the extent of tying all 3 on / off functions into a single on / off function that controls all 3 simultaneously.
I might even be able to sort out a means to step-down volts / amps from the machine's main power to accommodate elimination of the batteries as well. I really appreciate your video.
When you peeled the sticker off the ruller part, I heard stylophones in my head
I don’t think the device is “tracking” movement. Instead, I think that every position along the range has a unique combination of data, or “waveform” as you put it, coming from the sensors. It simply reads the data and spits out the value for that data reading in any position along the range. Since the sensors are spaced slightly differently than the grid, every position will have a unique “waveform”. Clever but pretty simple really.
I totally agree, and was going to comment the same thing.
Every position has a unique readout, just like letters in the alphabet. If you zero at position "F" and you move it to position "K", it will display that you've moved it 5 positions. It doesn't need to recognize every position you move it across (back and forth), bit simply displays the delta distance between the "zero" position and the current position.
For this to work, I believe the width of the "finger pattern" has to vary slightly for each "finger". Otherwise, moving it one "finger's width" would read out the same pattern as before.
It's definitely counting all the time, on every movement. I have one, made of steel rather than plastic, which used to be faulty, where it would skip 5mm suddenly once in a while, and the more you run it back and forth, the more error it would accumulate. I repaired it by placing some Kapton tape over the PCB, so it doesn't touch the metal. Had it been sensing in absolute units, it wouldn't accumulate error, the error would clear momentarily. It's also not the case that the short was triggering some button action, because what sensible button action can there be for skipping 5mm in either direction? I think 5mm is just the pitch of the scale. Maybe there's an absolute scale that it reads but it's only 5mm short and repeating, it certainly doesn't have 160+mm of absolute scale. I don't think the reading is entirely continuous, it could be in discrete time steps, but as long as between its readings, you don't move more than 5mm, it's doing OK. Actually maybe should rig up a scope or a logic analyser to it and see.
If you even just look at it, at the board beneath the scale sticker, it has a structure that just repeats every... probably exactly 5mm.
yes this is correct, and actually there is nothing to do with waveform, just binary code, each sense pad is read as a binary value and indeed not a single position has exactly the same binary value so we can map directly the resulting binary code and the matching decimal.
@@SianaGearz no, it does not track anything, i explained the principle in another comment. What you saw is correct, but the assumptions you make are wrong, the principle is very simple and on these small caliper the target pattern will wrap after 30cm, which is longer than the physical length.
The principle is that each sense pad is interpreted as a bit, and the target pattern is designed so that no bit code will be identical for any given position on the full length, it is the same principle as grey code by the way, the principle used in most encoders. So its just an absolute linear encoder based on some flavour of grey code.
On your caliper one (or more) bit (aka sense pad) was stuck, which leaded to an error occuring each 5mm, would have it been another bit the error would be different.
@@lo2740 but the sense pads are in line with each other on the PCB, it doesn't form a Grey code, impossible. Is it a De Brujin sequence?
Nice work Clive . It uses interdigital capacitors & a vernier effect . The unused buttons are almost certain to be associated with the SPC ( Statistical Process Control ) port ( Data port ) , used by some manufacturers to monitor production . Keep up the good work !
Some can have a fraction/ inch display.
Besides SPC there are a number of data communication protocols used in calipers. Cables and boxes are available for expensive calipers to connect to a computer but the cheap ones don’t even tell you they are there. They are hidden under unlabeled covers.
neat to see the vernier is still in there. surprised Clive did not recognize it.
Thanks! I actually have one of these for 3D printing. I have a nicer set from Mitotoyo but those are not needed in the house, so I have this cheap set on my desk just to have a reference when designing something. I had pulled them apart on accident and was wondering how to put it back together, found your video and it was helpful!! Fixed the calipers and now can use them again. I need to print a new battery cover though.
If your caliper go crazy and start show random numbers, its worth try to take it apart and clean sliding parts. Mine start working again and I spare some 20€, metallic one.
"I'm going to remove the battery"
*CLONK*
"The battery is out."
I have one just like the amazon one, but not plastic caliper...used it very little but on second battery change it wouldn’t work unless I pushed hard with the batt cover off. Then I saw a small sliver of metal on the table. It is the middle piece that makes contact with the plus bottom of button battery. Tried to solder it back in, i possible, so I used copper braid (very thin) solder wick and soldered that in. Can’t put the cover back on but the battery sits so tight it’s no problem. At least got it working again. Very cheap battery contact point.
@@shader26 Ugh, I've got a Mitutoyo that's doing almost the same thing. The battery tray is junk across all brands.
It's worth noting that there is a little cover that slides off to give access to the data pins without taking it apart.
Incredible how it stays on track even after racking it furiously. this used to be only possible with the expensive ones. Shows that even that tech is simple and cheap to manufacture
could just be the trade-off for lost precision.
the thing is when they start to have trouble its permanent. i used one that never kept its zero. i had to constantly try to clean it and zero it out each day.
𓂸... What?
@@operator8014 , well if you have a tenth of numbers to keep track of, you may be able to do it ten times faster, right?
So it could be that both fast tracking AND double digit precision is still only possible with expensive calipers.
I have one of these. Long-term review here. It's held up pretty good and has been through tons of dogshit. I was 12 when I got mine and am now 20. As mentioned in the video, there's usually no need to go into the precise measurements (there are more precise and better instruments than the verniers). These have been submerged in oil, water, and doused in glue. Swapped the batteries out and got it back onto the bench. It's great value. I cannot recommend this for the professional worshop obviously, but for a hobbyist machinist/engineer, by all means, it's one of the more reliable things China has produced.
For the best part of 48 years I chose after a 5 year apprenticeship to go into heavy engineering even though I was and still am short arsed and never been in double figures in weight, I have a knackered back, shoulder and wrist to prove it .
Years ago on a 10 ft vertical borer we only had mechanical verniers, and believe me, using a 6 ft one that weighed a ton and trying to and a achieve a “feel” across that diameter and line up the best line that our eyesight could see, then put a final cut on was at times with a finger up our backside.
With the introduction of cmm measuring final inspection we on the shop saw digital verniers.
The “feel” we needed wasn't needed, in fact I personally took a measurement, closed the vernier down, and zero the readout 3 times and If I got the same reading that was good enough for me and took the cut, I will add at this point machine tools were getting digital readouts but thats another story.
The one big thing with using the digital verniers was that the component would be wet from coolant used for cutting the component and they really did not like that, and all of us had a can of WD40 in our tool chest to combat it. Then they introduced a waterproof version that was 6 times the price !!!
These days I work on much smaller components.
I have a lathe and other bits and bobs in my garage and have purchased one of these cheap and cheerfull carbon fibre verniers and can only agree with you what a lovely piece of kit they are … thanks for your time …. I love your you tube channel … Take Care
That is actually pretty damned impressive! I figured that cheap calipers like these (I see this type often) would be absolute garbage, but it seems I was wrong, and I am very okay with that!
“So i’m going to remove the battery”
*firm whack*
“The battery is out”
This is the humor I came here for
That cracked me up too, both the whack and the announcement
Lidl/ Aldi did a version of this nearly identical, I’ve had it for years, cost I think about £5.00, use it very regularly and accurate enough for the average home uses :D
Same. Use it all the time. The Lidl one looks like a Rolls Royce compared this plastic one!
I've got the ALDI/Workzone one.
Had it for about a decade, and it's still working perfectly.
They recently did an updated version, with a circumference option, which is handy, but the build quality isn't as good, in that it is a bit gritty in operation.
@@ConnectMortgages The Aldi one I have is full metal and has two accurate digits behind the decimal point when measuring in millimeters and a kind of thumb wheel with which you can very slowly increase the distance to see the 100th of a digit increments one at a time, if you want to. It did cost 9,99 euros 'though, when I bought it (in 2006), which nowadays is significantly more than 5 British pounds.
@@jiriwichern This cheap plastic one started not measuring accurately last week. I think it's too cheap. The Lidl 'Parkside' metal one still works great!.
The "origin" button on the Mitutoyo ones at work is used when replacing the battery. Unlike the "zero" button, which holds a temporary offset, the "origin" is used to initialise the counter and in effect permanently store the location of zero... until the next battery!
These cheap plastic verniers are brilliant!... I bought several of them to leave dotted in strategic places around my workplace... Plenty accurate enough for a quick measurement 👍
Can we stop and appreciate how smoothly he popped that battery out?
There are actually four methods of measuring, not three!! The fourth is the 'Step' measurement and very useful.
This is the opposite end from the depth gauge. Close the caliper and you will see that the ends of the two parts are flush. These can be used for step measurement.
"Let's grab a random nozzle" - that's one of my favourite party games.
The encoding used in this is of the absolute type. It's not an incremental count from one end to the other. It actually computes a position value at any given position along the scale based on the capacitive "bits" of the scale. It doesn't matter how fast you move it, it won't lose it's position. Now get the scale slightly wet and it'll lose its position until it dries off.
after having this a while i found the unit kept reseting the value like zero was being push. thanks for taking it apart so i knew what to expect. cleaning all contacts with nail varnish remover and working great again now!
Slightly crunchy probably means glass reinforced plastic. You also missed the top shoulder to measure depth as well
Bolt/screw length.
Another minor trick: find screws under decals/stickers by applying finger pressure over the entire surface: screw holes beneath the decal are betrayed by the spherical-section deformation of the decal (think: golf ball dimple), best seen by direct reflection of a broad light source; X-Acto-ing a cross or trefoil inwards from the edge of each hole, through the decal, leaves the decal largely intact, allows for insertion of the driver tip, and retains the screw(s) where needed for later re-assembly.
I have a metal vernier of similar lineage. Beyond repair -- cracked wind, missing battery compartment cover, missing buttons, etc. -- and am wondering if the digital gubbins from the plastic variant can be migrated to the metal one -- the advantage of which is the ability to scribe lines on work pieces.
@Gazr Gazr ftfy 2:35
@Gazr Gazr he mentioned the tail hole depth on the small end but most people don't know you can use the top shoulder too. Calipers can measure in 4 locations. OD/ID/depth/shoulder
BlondiHacks says always wipe the jaws clean before zeroing out.
Also use your thumb to apply a little pressure as you zero it, try and maintain the same level of pressure when taking measurements.
@@Nate3094
I like to just gently nudge it up and then let it go. If I need to be sure of the exact size, I take 3 or more readings and rezero each time.
at my job i used them all the time. mine had a little wheel as a thumb rest and you could turn the wheel with your thumb to slide the bar precisely. i personally hate the model that dont have the little wheel. its way harder to use them.
@@2000jago try opening the jaws without the wheel, you have to put your thumb way forward and try to grab the unit to drag it open. with the wheel thing, you just wind it up backyard and the module scoot backward.
I always wipe the jaws with my bare fingers and feel for foreign matter, before pinching the jaws with thumb and middle finger, while resetting the zero, with my index finger.
It's second nature now!
13:00 Hi Clive. This pattern is the grey code pattern for encoding. This is a grey code linear encoder pattern. Grey code being important as it is an absolute method of measuring position regardless of power loss. :-)
Agreed
No, it's actually a 7:8 Vernier scale. Human readable Vernier scales are 9:10 ratio, but for obvious binary reasons this scale is based on a power of 2.
I almost laughed when I saw Vernier on the listing but I'm impressed that it is actually used.
Grey scale is different in that only one bit changes as the number increases or decreases. That's not the case here.
@@chrishartley1210 Vernier scale is not absolute. Grey code is.
@@StreuB1 it's an absolute linear encoder, that's why no mater how fast he moved it, the reading was picked up.
@@StreuB1 I agree, but that is still a Vernier scale.
Grey code goes (in binary) 0,1,3 2,6,7,5,4,12,13,15,14,10,11,9,8... Please tell me where you see that pattern.
I worked with grey code 40 years ago (and since), it's not something you forget in a hurry.
That handle without the measurement sticker over it looks like a very long but minute stylophone 😅😅
Great vid BG, I take my hat off to you for having so much patience.
Nice to see these actually work as claimed. I'll still take metal ones at twice the price, even though the sensing mechanism is probably identical. I trust that the jaws aren't going to wear down and affect the measurements. Also sometimes what I'm measuring is hot enough to melt plastic, which is manageable with the metal-jawed ones even though the measuring part is cheap plastic. I just have to be quick about it.
The circuit board and the pattern on the caliper body function exactly like the vernier scale on the analog calipers. Put simply: on a millimetre scale, you can't judge if the line is at 0.4 or even 0.35. But having a set of lines that are 1mm less 1/20mm allow you to then see which one of the lines best matches another one on the millimetre scale. The human eye can't see well where exactly between two lines another line falls, but it's VERY good in seeing whether two lines match or not. So then, you read the millimetres off the 0 position of the vernier scale - that would be, say, 3mm and something, then you note that the lines marked 7 and 8 almost match, but the one between them matches perfectly. so that's 0.75mm - the measurement is 3.75mm.
The working principle of these electronic ones is exactly the same, only electronic, and it tracks movement instead of position. As you push the slider, the pattern of "fingers" with alternating potential/no potential causes a pattern of 3 electrodes or 4 electrodes sensing to move much faster to and fro - which allows the electronic to determine how far the slider has moved.
Based on the maximum length this measures, the number of electrodes and the number of fields, it should be possible to calculate with which resolution and thus precision this works. But I can't be arsed right now.
I was thinking the same thing, have a set of old school Vernier calipers at home as well as my cheap digital set. Best bit you don't need batteries and they are pretty accurate. We also have big 20" and 24" Vernier scale ones at work. The internal measuring faces are ground on the back of the main faces so you allow .400" or .500" depending on the Vernier. All the above have a metric scale on them too.
Thank you for explaining this!
Bloody hell. I never imagined these would be so interesting to learn how they work. Amazing technology huh!
The confusion between accuracy and precision near the start of the video had me shouting at the monitor. They are not the same thing at all
And what's the difference?
@@bogdan_n Image 2 sets of callipers
Set 1 - Always returns the correct value to 3 decimal places when measuring a known length
Set 2 - Returns the correct value +- 1% to 3 decimal places when measuring a known length
Set 1 is more accurate than set 2
Both have the same level of precision
@@Bob_Burton Either i'm too dumb, or you don't know how to explain, or a bit of both.
But from what you say, i see 2 situations:
1. The first set indicates the correct value (precision class 0) and the second indicates a value within 1% of the true value (precision class 1)
So, they don't have the same level of precision.
or
2. doing the measurement multiple times. the first set gives the same indication each and every time, while the second set gives different indications, varying within a 1% window.
In this case we are talking about the repeatability (or, in some languages, the fidelity) of the instrument.
Or it's just a language barrier, as in my language we have the "precise" and "accurate" terms, but they are synonyms.
@@bogdan_n They both have the same level of precision, ie 3 decimal places, but one is more accurate than the other, ie one shows the proper measurement and the other doesn't
Suppose the second one always gives a result 1% too high instead of giving variable results. Does that help understand the difference ?
@@bogdan_n
One is how close you are to the actual value (accuracy). The other is consistent you're getting the value (precision).
A great visual is target shooting.
-hits are all over the place, but your average is dead on. Poor precision, good accuracy.
-hits are all over the place, but the grouping is also way off the bullseye. Poor precision and accuracy.
-tight grouping, but nowhere close to the bullseye. Precise, but poor accuracy.
-tight grouping and right on the bullseye. Great precision and accuracy.
Thanks Clive! You saved me after I carelessly took apart my 12" (300mm) digital calipers and didn't note where all the pieces came from as they just fell out after I took out the screws in the wrong order. Although mine were a bit different, I was able to learn enough to reassemble (after repairing a solder joint on the + contact) and it's now working again! :-)