I used to design and repair test and control equipment at a major Quartz Crystal manufacturer. This was "not recently". We did everything from growing the quartz through building TCXO, OCXO, DIL oscillators, SAW devices and Filters. Our DIL oscillators used a real thick-film modules, with the chip bonded to it, and connections made with bond wire. Partly because (in big volume) it was cheaper, but also because it allowed you much more space to "do things properly" - with one of those things being proper decoupling. Dividers were quite common, partly because it is hard to make good crystals at certain frequencies, and there was also a "size" thing - good 1MHz crystals are quite physically big. Did you get a sample of the gas when you opened it? Mostly they're filled with Nitrogen with a tiny bit of helium. This is part of the controlling the ageing, the helium makes it easy to check them for leaks very thoroughly. The mounts were crucial, get them wrong, and you get a lousy, rotten xtal. How you hold the crystal changes its characteristic. Get it wrong and you'll get a horrible product with issues like "band breaking". For crystals in conventional packages - those two clips means you hold it in just the right way, and with just enough "spring". It's much hard with DILs and that's why you often see three posts. If you were seeing substantial shifts and changes in ageing following a shock, then bluntly, your crystals were a bit crap. The phenomenon has several names in the industry, we called it "sleepy crystals". It really was (and still it) one of the industry's dirty little secrets. It is a sign of a production problem. I'll explain that later. In extreme cases you would have a product sat in a drawer for a few months where the Oscillator wouldn't start at power up. If you (very carefully) took it apart, you would find the ESR was through the roof, the Q was pathetic and if you did get it to start oscillating, it was likely to have been on a "band break" - so the frequency would be slightly (but significantly) offset. Bang it on the table - and all would be back to normal again, until it was left for ages. One of my first post graduation jobs was to design something which could detect this problem without the whole "waiting a month or two to see what happened" thing. I designed a system, which used the then standard ISO methods of measure frequency and ESR, except at very low drive levels. You would then gradually increase the drive level, watching to see how F and ESR change, until you are at maximum power, then you wound the drive level back to the zero again. You plotted the results on a graph, and you would get a fairly classical hysteresis curve, and the bigger the area inside the graph, the dodgier the crystals. You only had to leave the crystals alone for a day or two, per-test to get a clear result. I'm being called out on an errand now, but I will return later and explain where the phenomenon comes from.

Wow, that really took me back. About 20 years ago when I was working for NEC at a PC factory in MA. We were getting our PC motherboards (MBs) from SCI Technology in Tampa FL. We started seeing a lot of PCs fail on the assembly line. Some of the MBs were DOA, but most (90%) were just working badly. After looking at some clock signals on one of the poorly working MBs, I zeroed in on one of those little metal oscillator modules. The clock was off-frequency, so I replaced it and the MB worked! We powered up about 20 of the failing PCs and I used an RF spectrum analyzer (with a probe antenna) to observe the signals from the boards. Since these boards had six oscillator modules, I mapped out the RF profile from a good MB and compared frequencies emitted by the failing MBs. Some of the failed MBs had more than one failing oscillator modules. The failure pattern of which module and the shift in frequency was random. I decided it was a QC problem with the oscillator modules. However, since some of the off-freq modules came from different vendors, I deduced these modules were somehow damaged at the SCI factory in Tampa. SCI said Nope, no way.. I had a collection of failed modules, a microscope with a Polaroid camera and a dermel tool.. I did a presentation for the NEC VP of manufacturing and was quickly on a plane to Tampa. The photos of the little cracks in the quartz disks told the story. Because I'm a Ham Radio guy, I knew that dropping a radio Crystal 4" onto a desktop would break it. So I knew what to look for at the SCI factory. I watched the guy that loaded the tubes for the PCB parts loading machines. Nothing unusual. Then late in the afternoon, I saw him unloading the plastic tubes from the module vendor, he was dumping them into a hard plastic tray, from a height of about 6 inches!! Afterwards, he hand-loaded them into the special tubes for the parts-loaders. He didn't believe he was breaking them. I shown him the pictures. Another Case closed.. :)

I don't know jack shit about what this component is about or what to use it for, but was hooked with your narration style and the way you tear down baby electronics components, sorta reminds me of how I used to tear down my toys when I was a kid to see how it works 🙏🏻

Fascinating video Dave. Crystals and resonators belong to the dark arts, just like fortune telling and antenna design.

Nice video. BTW, your viewers might find this interesting: this device is a thick-film hybrid. Meaning, the traces are not etched, like a PCB. Rather, they are made by silkscreening on a conductive paste and then firing it in a kiln. And what looks like solder is probably conductive epoxy. I don't recall if you ever did a video explaining hybrid circuits. I used to design stuff like this back in the '80s.

Thanks for going the extra mile and figuring out what that noise actually was. I had no idea it was a 8Mhz crystal with a divide-by circuit. Good stuff!

I'm not an electronics guy but I love your videos. I find this fascinating how when we build a device each individual component has so much detail and knowledge behind it. Standing on the shoulders of giants indeed! Even Wozniak was just taking complex components already designed by someone else and plugging them together in a novel way. All around the world there are a small number of experts on just one topic I guess - capacitor construction, chip fabrication and of course crystal clock circuits ☺️ it means that ordinary guys can take a raspberry pi for example and all that work has already been done for you so that we can concentrate on the target application, software and maybe very particular hardware for the application in hand without having to learn about oscillator circuits or PCB fab!

I'm so happy that you're back into the interesting stuff again! No debunking videos, just fun and interesting tests and experiments. And equipment shootouts of course! You can almost feel that you actually enjoy making the videos again. Thanks man!

Absolutely fantastic video dave - one of your best imo. What I like about this is not just the sweet tear down of those crystals, but the way you've demonstrated how bypass capacitors have an effect (and how distance from the connection makes all the difference), but also your mention about vibration too. I've come across odd ball issues where a system was suffering jitter because the can was not grounded (on a 2 pin crystal), and I've also seen issues where another system had jitter or something because the can wasn't supported (floating) and was susceptible to vibrations from road traffic 20 yards from the house lol. People think these things aren't relevant, but they are factors.

"Hi, it's time for a quick 2 minute teardown" * video goes on for 17 minutes *

Very cool Dave. I used a couple of these about 35 years ago. Never considered what is inside. Thanks for the insights - very informative.

Hi Dave This channel is one of the best. I have used these oscillators in many of my designs and always treated it as a black box. Thank you for the informative tear down. Keep up the good work. Thank you.

As usual Dave, your videos are explained in great detail and clarity. It's great to watch and learn.

The reason for using an 8MHz crystal and divider is that if you used a 1MHz crystal, the crystal would be WAY to big. About the lowest frequency you can get in an HC-18 package is a little bit less than 4MHz, and they were pushing it when you got one at 3.579..MHz (NTSC colorburst frequency). Now you know.

After all these years you've been teaching the world. Thank you so much.

I would find it interesting to see temperature compensated (TCXO) , oven heated (OCXO) and voltage controlled (VCXO) oscillators aswell, in comparison to the regular oscillator.

Internal cap is just presumably intended to only absorb the current spikes from the CMOS state transitions within that chip, which is why you need to start playing around to get things right when you have a load connected to the output. I've personally never had much luck putting bypass caps on things. I do it anyway though. The signals usually still look like they're strong enough to take satellites out of orbit...

Everyone here should have a small stash of oscillator modules. Much easier to get your test circuit running when you can rely on the oscillator working without much fuss. Often you can find them on sale from reliable sellers as well.

You did a great job adding that image of a teared down xtal on Wiki, it helped the internet grow !

That internal bypass cap IS necessary, since these are high frequencies here (8MHz) vs. the 'user' frequency of 1MHz which needs to be bypassed as well.

Dave more videos like that. We need people with work experience to share their life experience and achievements here. Very nice video. Comments were even better. You the man.

Fantastic. The hint and prove with 8MHz is genious. Cheers!

I have attended this interesting demonstration in suspense mood . Your approaches differs. Many thanks !

I cut open crystal packages in the 1960s and saw springs in some of them as well. This is the first time I've seen crystals with little divider chips. Cool! Thanks!

I just realized Dave is the Steve Irwin of electronics

I’ve taken a few of these apart that used two discrete smd rf transistors to form an oscillator and buffer. The resistors were part of the ceramic substrate and the caps np0 (presumably) standard chip caps.

Thanks for cutting up one and showing us all.

Such an interesting video. Lots of effort made by Dave and lots of things learnt by us.

Really neat. At 15:45, and previous close ups, it looked like the lower left pin was poorly soldered to the ceramic PCB. Also, I wonder how the metal lid affects the performance? Perhaps if the crystal circuit is very weak, it's susceptible to external noise? Back in my manufacturing consulting days, I had a client who was a contract manufacturer, and their client had them doing some 500 piece build. They were getting about 50% yield. Long story short, their client fouled up the PCB design a little and had the CM driving some heat sinks on the PCB with a mallet. Half of the time they were completely assembling the PCB hammering the heat sinks on, then soldering the crystals, the other half of the time they were soldering the crystals then hammering the heat sinks on.

Actually 1-2MHz crystal is extremely difficult to make, so these 1MHz osc resonates at higher frequency, like 4MHz, and divides down to 1~2MHz

Gravity must be higher there, here this was more than 2 MINUTES. LOL. jk, very interesting video. Didn't knew how are those inside.

The capacitor between power and ground is meant to add extra power during flip flop operation. Decoupling capacitor.

Excellent video, a must see for anyone designing digital circuits

12'19: Did not know you wrote your own CAD software. DaveCAD. Love it.

Yeah, I took one of those apart once. All that was in it was the crystal, and a 74LS90 in an SOIC14 package, all on a tiny PCB. Big deal; I way hoping for earth-shaking alien technology! Bummer.

I didn't really understand bypass caps but this definitely got me some good understanding of it and about EMF interference, good video ty.

One of those option resistors is open collector output. Pulls the output up. Another one is divide by 16 option.

As an engineer at Abracon, I loved this video

We had a supplier rev up a sub-assembly... our application didn't require ethernet, so they took the (big, expensive) chip off the board. This meant they didn't have a clock source for the rest of the board, so they dead-bugged on a DIP oscillator... and proceeded to have real squirrely problems... sometimes the boards would be good, sometimes not. I got a free trip to Ottawa to help with the problem... turned out that putting bypass caps on the deadbugged DIP oscillator cured the issue. If you read the literature they recommend bypassing them!

Thank you Dave! I really appreciate your explanations of how electronic works.

Amazing teardown of oscillator.

The resonance frequency of the springs should be in the low kHz range at maximum; I suspect it to be even below 1 kHz. This is so far below the quartz oscillation frequency that the springs won't be excited; the ends won't even oscillate at any significant amplitude. They behave just like a solid mounting post. I think they act as a vibration and shock damper to prevent the quartz disk from breaking due to mechanical shock.

Definitely worthy of a thumbs up. This was fascinating!

12:06 - WHOAWWW! DaveCAD 3D! New Version is out, it seems :)

I don't know what this is, but I guess I'm learning something. Never know if I ever need to ever know this, never know. Hey, I know ABC and 123 because I paid attention and now I know how to use it. Thank you professor.

If you use the Doofenshmirtz Evil Incorporated tune as intro.. these will just perfect!

Fun fact...the OCXO in spectrum analyzers are also mounted on springs!

(@2:41) - check out the piss-poor solder connection at the lower left! That ought to fail the next time someone drops it on the floor! 😃 The others don’t look too bueno, either!

As long as the spring pressure exceeds the oscillation frequency vibration it's a superior setup ..think about it the contacts are spring loaded so dropping it won't throw the values off as much if at all

Always wanted to look inside one of those!

Reminds me of 80's computers, TTL signals looked like a roller coaster.

Hello! Dave You are such a genius, many thanks for this explanation, I appreciate always your efforts. Thank you again.

I've teared down dozens of these and those are all the same. Crystal, op-amp and couple of passives. That N.C pin is used variously, sometimes with tuning cap, sometimes something else.

The bumps also allow cleaning solvent to flow under the package for defluxing.

I've always wanted to tear these apart but I don't have too many of them and have always wondered if they had a bypass cap in and run out as well, kickass video man! As usual, awesome awesome stuff! It's always fascinating to look inside of stuff whether it's something from the 50s or whether it was in last year's cell phone model LoL :)

Great surgery Mr Jones, like the orthographic DaveCad.

I can't believe how good your videos are! Legend

AFAIK in these oscillator modules they always use dividers and/or PLL multipliers to ensure an exact 50% duty cycle.

Definitely did not expect the inside to look like that

I've always wanted to pull one of these modules apart, Dave, So thanks for doing it for me. ;)

Very educational. Thank you Dave!

Sweet techbits, brain feels better! Thanks! So, any cap is better than no cap!

Technically the quartz IS THE OSCILLATOR. It is called a QUARTZ CRYSTAL OSCILLATOR. The electronics drive the quartz as you should know. The electronics are not a resonant circuit. THE CRYSTAL RESONATES. The analogy is that a clapper strikes the bell, but it is the bell that resonates. Perhaps contemporary usage has smeared the older form of language into indistinction.

Datasheet on the oscillator ship from the second oscillator (the one with the busted resonator) - it's s seiko part. www.npc.co.jp/en/products/xtal/clock-oscillator/5054-5056-series/

Great video...! Thanks Dave

Time for a 2 minute teardown... for 17 minutes!

I have jumped into the DeLorean specifically to add this comment in the past.

Dave is great but also take a look at Mr Carlson's Lab.

Good you have an Indonesia subtitle for this

The "cushioning" coils supporting the crystal , the material is silver ? , interesting video !

Another great vid Dave!

Willing to bet that the bypass resistor is used for switching the frequency division to match the crystal.

Love the teardowns!

(15:14) Might the resonator frequency be 32.000MHz? The ripple looks like it's 4X the frequency of the signal you're probing.

Is it possible the springs are clips? Perhaps the crystal disk would be added after the PCB is built and then soldered on to make assembly easier.

Dave, Can you make a video about other types of oscillator? TCXO, OCXO, VCXO and SAW resonators. What are their uses?? Thanks!

@0:30 .. Surprised. I have an ancient colorburst crystal in a miniature tube (cant recall if it's 7 or 9 pin) envelope - looks identical. I guess I always assumed the guts of the more modern cans were much smaller.

Good work! It's really useful for me.

3:41 - Maybe it's the lighting, but nothing appears to be connected to Pin 1! (3:38) Update: Ah, it 'could' be used as a tri-state enable (never seen one) or simply not connected.

Excelente video Saludos desde Argentina

I can't believe that he hacked the top off of the can instead of sawing the two halves apart at the weld between the two container halves. The internal bypass capacitor is understandable as the power input pin is not supposed to be a signal output pin. Ron W4BIN

Thank you Dave! I always wanted this.

Thank you

Did never guessed ther were componnents within the packaging of thiskind of crystal :)

Excellent sir...

Teardown Mondays!!!! yey!

Great aphex twin track to!

Theres a datasheet for that oscillator IC 613N1 they could be purchased separately

Hey guys. The tech behind Crystal Oscillators is pretty new to me, so I was hoping to get a couple of basic questions answered, for which I was I was struggling to find answers online. 1) How exactly are the fixed output frequencies of an SPXO set? We have many 'standard frequencies' such as 10,12,16,20 MHZ, etc. Is it only due to the way the crystal is cut, or does it also depend on the other supporting circuitry within the Oscillator? 2) How does the circuitry for a programmable crystal oscillator (Such as Epson's) differ from a fixed frequency oscillator? I know these involve 'blank' oscillators that can be programmed to a desired frequency using a handler. Does it contain any circuitry such as programmable non-volatile memory? Thanks in advance!

Why are ceramic PCBs used for these purposes? What's the advantage compared to, say, ordinary FR4?

Can you connect the little buffer to its own power supply? That way you can see the effect while the buffer is properly decoupled. Nice video. Maybe people now also understand how important it is to decouple properly with boost converters etc.

Super! Thank you very much!

The moment I saw the higher peaks I knew the the crystal was a much higher frequency. A 1 Mhz crystal would be about the size of a half dollar coin. Most crystal oscillators in the 1 to 5 Mhz range are all higher frequencies and then divided down to 1 Mhz.

"I can just buzz that out to confirm, but I'm sure it does." Well no, Daiyve you can't be SURE.

Very interesting Dave-so you are studying for you Radio Ham licence ?

You should try to show the voltage drops in the GND traces too, the effect of these is shifting the GND at the device(s) which obviously is not a good thing either.

there is only one question left) what is a quartz resonator after all? Is it a filter? a frequency allocator or is it a frequency converter? what frequency signal should I send so that the resonator is excited and begins to resonate. From physics, we know about resonances at matching frequencies, well, if quartz is 4 kilohertz, then I have to send a signal to it exactly 4 khz, no more and no less, and eventually get a stable frequency of 4 khz and its harmonics. But now the question is not about harmonics. I know there are filters that pass through themselves only a narrow band of frequency to which they are created, but quartz seems to emit itself. Hence the question: WILL I BE ABLE TO MAKE QUARTZ OSCILLATE 4 KHZ BY APPLYING 1 KHZ OR 11 KHZ???? OR, WILL I BE ABLE TO SMOOTHLY CHANGE THE FREQUENCY WITHIN WIDE LIMITS AND QUARTZ WILL CLEARLY BEND ITS FREQUENCY, WITHIN WHAT LIMITS OF ITS POWERS?) If we tap on an acoustic guitar, we will hear the resonance frequency of the guitar body! it turns out that a short pulse was applied and the body responded with a pulse frequency of 800 hertz. How many pulses should be applied to quartz so that it resonates continuously?

I wonder if the higher frequency ripple is due to L/C resonance in the transmission line on the output. It is terminated with a dummy load, but there are no guarantees that the XO is driving at 50R or that the transmission line itself will be matched. Just a thought.

Awesome, Dave. :)

Finally some artion: PIcasso on the oscilloscope!