TSP

*A minor correction to the video: The maximum hardware sensitivity using the InP input preamplifier is 7.5mV/Div at 256GS/s and using the SiGe input is 4mV/Div for the 128GS/s models. The remaining displayed vertical levels are DSP processed. The noise measurement is of course still correct and valid as are the shown ENOB and linearity numbers.*

Video reported for pornography

The entire list of potential customers could probably fit in a single coffee shop to talk about phase shifters in 110Ghz scopes.

Can I use this to trouible shoot my flashing led arduino project?

You know you've made it in life when Keysight will send you something like this. Not only the device but boards and decapped chips. Absolutely stunning.

10 picoseconds - the time taken by light in a vacuum to travel approximately 3.3 mm

I’d buy one, but I already have a 1054Z.

The video where Shahriar is literally nerdgasming for a full hour..... and so is everyone watching. Phenomenal technology!

Nice sturdy-looking handles at the side of the instrument - to hold on to and keep you steady when you hear the price...

(sees ADC board back side) So that's where all the 100n capacitors went!
Thanks for the awesome video, love it!

10bit @ 113Ghz and 4 channels, I just can’t wrap my mind around that! Thanks for the video, no way I’d ever get to see one in use otherwise. I work with ultra low frequency stuff usually 10Ghz or lower so I guess that’s basically DC these days. Amazing.

I'm amazed that Keysight is letting the world see this equipment in such detail. Typically I would expect something so pricey and niche to be kept under lock and key. I can't believe all of that is required for a SINGLE channel of the scope. Absolutely incredible engineering. Totally worth every one of those 1.3 Million dollars.

You seemed extraordinarily comfortable waving that metal pointer around that million dollar oscilloscope's screen. If keysight had dropped something like that at my doorstep I would be afraid to even breathe near it.

What an absolutely incredible engineering achievement. It takes a very special company with a wide range of talents and a wide variety of fabrication technologies/abilities to make a product such as this. I can only imagine the pride and accomplishment felt by the team who were fundamental to this device's creation. Great stuff 👍

That is by far one of the most amazing things I have seen on CZcams. Being able to actually see that high frequency sinusoidal waveform, wow! That is serious engineering in all electronic voodoo disciplines. Thank you for doing this video, and you are correct, the engineers that designed this should be very proud.

Wow, totally amazing teardown on a totally awesome oscilloscope. It's impossible to not be impressed!

Wow what an amazing instrument! Really loved the breakdown of the different boards!

That is a truly beautiful piece of equipment. It is more of a piece of art work than any other equipment I have ever seen.

I'm speechless, with tears welling up.. What an impressive design.

And here I was feeling fancy with my 200mhz Siglent.

pretty slick engineering no question.......hell of an analysis/demo too

Next level GHz. :) I'd love to see some wallpaper sized (4K+ res please) photos of those RF parts and chips.

Great video as always shahriar. Just could you please zoom in more when you are analyzing the front end circuitry.

If engineers had a collective standard of beauty, this would exceed it by several orders of magnitude.

Just an amazing video and piece of technology. Thank you for sharing this!

Man, that board design.. incredible. I'd love to just look at the routing. Of course the indium phosphide design is next level awesome, and look forward to other foundries opening this technology up. Huge props to Keysight...

The PCB assembly alone is extraordinary. That A/D PCB must have taken a lot of planning and consideration for assembly, reflow, testing, etc.
The design......obviously next level. Stunning opportunity to see technology like this.

Shahriar, every time i sit at my desk i feel good about what i have there about a house and a half worth of equipment and then i watch a video of yours.... takes me two weeks at least to recover from the shock

I wasnt expecting to see that monster in your bench that fast.

I work as an engineer in a small company. Usually i do both schematics and layout (like i said small company). I would LOVE to some day layout a board like the digital processing board on this thing. It looks really fun to do. I wonder how long it took.

Great video. Would like to see some applications which have demand for this type of equipment. Hope KS lets you have it again for some experiments once it is in production.

Woah, that's a crazy device indeed. The complexity of that project, damn.

Thank you for making it possible for the rest of us to see inside and outside a scope of this possibilities and price range.

Can't wait for the full review and giveaway :)

You would not be able to get me to even look at this thing before i'm convinced that my ass is fully covered, insurance and liability wise :D I did not expect to be convinced that this machine is reasonably priced, and yet I am. Stunning stuff. Thanks for sharing.

I'm going to wait until the Owon version comes out for $300

I wish I had a second life after the one I'm living to have a chance to work on these designs. Wow. Mind blogging.

Great explanation how it works. Thank you.

This is majestic!!

Excellent works

Amazing! You just almost restored my faith in humanity!

what the actual...
What a beast!
Great video too.

Great video (as always)! Do you think you could make an introductory video on distributed element circuits?

Can I get a student discount on one of these puppies?😂

I wouldn't even know how to turn this thing on let alone use it for anything. But it doesn't make me want one any less! 🤑

Great video. Thank you.

great video great info..its a lot GOLD in that box.

Very impressive piece of hardware. Thanks for the concise and accurate information.

That's absolutely crazy. I really have no idea how they measured those parts during the development.

Excellent

These are number i never expected to see in my lifetime and i have not even seen the video yet :P

Are you sure you are allowed to show this before 10PM?
Or at the very least it should be age restricted..... ;-)

I'm new to electronics and am using analog oscilloscopes to do "Oscilloscope Music''. I would love to know how the high sample rate on this digital scope performs on this task. This is a beautiful piece of engineering. Thank you for showing us.

Holy fucking shit, this thing is glorious. Every different board is a treasure of different engineering techniques.
And kudos to keysight for the samples, I bet the people that worked on it would be happy to see someone gushing over it. And at this level you could take hi-res photos of each component and sell them to other companies, and yet they wouldn't have a shred of the technical know-how to produce this beauty.

WOOW What an UNBELEVABLE TECH :O

Shahriar, It's great to see such an in-depth teardown of the tool. How long did they let you "play" with it? Do you have the contacts with Keysight through work such that they lend you such equipment?

At this level of price and function, I'd be very afraid to hook anything up to it! but it would look soooo good on my bench!

In my lab we have two URX Scopes 128GSps, they are not as fast as this one on the front-end side, but still impressive (the fastest is 33GHz). My opinion after 2 years of use is that they are undoubtedly amazing machines with excellent front-end and DAQ hardware. However (and I honestly hope that some Keysight colleagues will read this comment), I would have expected just a little bit more on the software and UI in general. I'm not saying that is bad, don't get me wrong. But we are talking about million dollars machines, I honestly would like to have the absolute best. In particular, I noticed that the stability should be improved, expecially while CDR or heavy measurements/math are used. In several occasions I had to forcefully restart the OS due to hangs. Furthermore, I'm sure that the UX (including responsiveness and even interface style) could be enhanced: controls are slightly less prompt than on the old infiniium scopes (which I loved, especially the 20 years old ones with that DAQ to GPU waveform bus

Wow, speechless!

Well, this is simply amazing! Is there a reason for the front end to be so messy? Why not make all four channels symmetrical?

OMG! Amazing!

Saw this at a conference today, the money they spend to get their products reviewed is certainly well spent.

Wow! What a absolute beast.
Guys, if you want to see things even clearer then you can use a magnifying glass in front of your phones screen.
It works really well.
Thanks for the awesome video. =)

still shocked and awestruck! mind blowing indeed. Are those signal lines in the acq board SIW or guarded striplines? Although the dispersion of SIW might be unacceptable here... Also, does it go down to DC or is there a minimum frequency input?

Just for some perspective.. you can capture light traveling less than 1mm with this puppy. That is a fast time domain. Useful at CERN. Probably overkill for weapons research :)

Normally I would not think of a scope as a phase noise measurement system, but with the jitter analysis package I am thinking this could measure close in SSB phase noise on mmWave sources. Any thoughts on this?

Let me guess - you have to send it back. :)
Excellent review.
Don't forget to grab one of eBay in 30 years for $500 to stick in the Lab. Mind you, I've a feeling that getting spare parts for the "repair video" may be an issue.. :)

Love for the fellow treckie!🙂

No word of boot time, fan noise or tap test on the inputs. Also I bet serial decode will be $800 optional extra! So I’m holding my purchase for now. :P

Anyone know where I can download the schematic and PCB layout for this.

Today I am trying to routing my first bga, with lpddr4 memory that works at 1.2GHz and CZcams recommended me that video like "ha ha ha" watch what really cool engineers do.

Keysight has amazing products! They’re also an equally amazing employer🤗. I work for another division over there, so very nice to see a tear down of this caliber on products on the other side of the house. Great vid! New subscriber here; you got me hooked on your tear down of the E4446a spectrum analyzer.

Shahriar, how does KS achieve such phenomenal phase noise?
How is the main 64GHz clock derived?

Thank you for your very comprehensive analysis of the new UXR Scope from Keysight. Are you on Linkedin?

I'm interested how the time domain waveform looks like after the samplers. It is new to me that the sample and hold circuit of the ADC is not on the same chip with the quantizers.
Does it look like as a series of step functions with different amplitude or impulses with different amplitude? Could you help me out with good article about it?

Holy ASIC's Batman!!

My impression of how the boards for such a high-end instrument would be made is this: Each board coming from the manufacturer would be X-rayed first for an initial visual inspection, and then would be passed through a flying-probe machine to check continuity of the traces. After the flying probe machine, the boards would then be placed in a thermal cycling oven and cycled for several hours and then tested again on the flying probe machine to ensure that the boards were manufactured properly and will have very high reliability over the service life of the instrument. Only then will the boards be passed through the silk screen presses and to the pick-and-place machines for the placement of small and dense components. The pick-and-place machine would be a high-reliability type like that made by Essemtec which has sub-micron alignment accuracy over the entire area of the board. To achieve this the machine would not only align to the fiducials, but also scan key areas of the board to account for any error in pad alignment before placing the components. The boards would then go to the first manual inspection, where the alignment of all of the components placed by the machine is verified and any missing components are placed manually. Boards which pass will then be manually populated with larger surface-mount components such as relays, coils, connectors and hybrid components, and then passed on to the reflow oven, which uses an inert atmosphere to mitigate any oxidation which could occur during the cycle. After reflow the board will then be sent for another manual inspection. At this point any through-hole components will be installed manually and soldered by a robot, after which the board will receive a further inspection. The boards which pass will then be throroughly washed and sent to a special facility with tight climate controls for integration of chip-on-board components. The process of integrating the chip-on-board components will be done entirely by hand, with each chip being secured with thermally conductive epoxy and then connected by wire-bonding. After the components are installed the boards will then pass through two independent inspectors, each of which will conduct the same integration inspection, and both must pass the job before the completed assembly will be encapsulated using laser welding. Each board after the requisite steps are completed will pass through several stations, each of which will conduct individual board-level checks to ensure that each board functions exactly as required. The individual boards will then be installed in a test instrument, where an initial calibration will be performed and operational checks carried out by hand. Sample boards from each run will then be burn-in tested for a full week and inspected once more before they are sent for integration into the product for sale.

I am rewatching this video i guess for the 4th time as my company about to buy one :D I was wondering, how did they manage to isolate all 8 lines per ADC in the frontend module. They look like they are laid out very very closely. Any ideas?

I just started to know what oscilloscopes actually are since 3 days ago. But I can still imagine how crazy those numbers are.

It beautiful 😍

The scope that we deserve but not the one we need right now :)

If you're still around in 25 years or so, Siglent will put this on your bench for $1M, which by then will the equivalent of $1k in today's money.
But for now: wow.

Can you show what that extra chip to the left of the daq board is? Can you also lift the heat sink of the hbm module to see which part they used?(hbm1 or hbm2)

Looks like I gotta hold out for the handheld version for use in the field.

"You're only ever as good as the tools you use." *Laughs in poverty*

Wow,!! thats the only thing i can get out of my mouth !!

There must be an enormous amount of reagent grade silver in that mechanical attenuator.
It is possible that the CMOS ASICs are made by GlobalFoundries as they have worked extensively in the past with Chartered.

I wonder how much skill and esteem from manufacturers is required to receive such instrument for a review and a teardown. Of course a lot!

Why did you blur out part of that ceramic package...???

I hope they let you keep it 🤓

This is INSANE !!! Cant wait for the Chinese clone for $19.95 with free shipping !

Scary gold

28:00 Interesting to see that the base of these dont seem to be ceramic but ordinary PCB material? Dont think I have seen that before, but it would absolutely be cheaper though.. for them that is.

Do you know what happen to the data after the dsp? It go to the CPU motherboard and processed by the CPU or the data is overlayed on the screen and the gui is runner's by the CPU?

What's the power consumption of that? Wouldn't be surprised if it tripped a normal 15A/115V breaker the moment you turn on the 2nd channel. :)

I have one and it is a very powerful tool

A nice hobbyist starter scope for my home lab.

The evolution of the laith!

This is a great video. The blank frames are really jarring though.

Giggidy Gigahertz!
just fkn WOW!