X-rays reveal Raspberry Pi 5's hidden secrets

No, I am not a doctor, but I do prescribe a shirt or the new metallic print of the X-ray Pi 5: redshirtjeff.com/listing/x-ray-pi-5-metallic-print

4:16 Electrical engineer here. One small correction - those wiggles are for something called length matching. When you have a high speed group of signals that all need to get from point A to point B, they all need to be about the same length , so they get there at the same time. In this PCI-e example, they happen to be differential pairs as well, but that's not the reason why they are length matched. If you look closely at the RAM tracings you can see similar matchings there.
PS: You did mention its for length matching later in the video. Sorry. i wrote the comment before i got to that point.

I need to seriously stop just glancing at titles! I thought this said "I X-Rated My Computer" which I was like, I can respect that... Don't know that I'd make a video about it, but you know that's just me...

It's very annoying to me that the Pi Foundation apparently went to the trouble to design a custom power management IC with Renesas but couldn't be arsed to include support for a step-down converter in it so that you could use any totally standard 27W or greater PD supply (9V3A) instead of needing the wonky custom 5V5A profile their own adapter uses, just to save a few cents.
Great video, though! As an electrical engineer, no major glaring issues that I noticed. Accurate enough for a youtube video! At least one or two of the chips you mentioned as having bond wires are actually probably flip-chip and what you're seeing are the breakout traces in the package (with no flying bond wires) but it's a minor detail and I'd either need to know more about the chips in question or take a closer look at cleaner x-rays of just the bare chips to be sure.

I run two Zeiss CT scanners, one can scan at sub-micron resolutions (Xradia)! Thanks for showing off this technology and the Metrology field as a whole!

A lot of small VIA's in a line are often a "fence" against unwanted signals propagating through the board between layers. A sort of faraday cage. The distance between the VIA's will be slightly less than ½ wavelength of what they want to block. This requires 2 (or more) ground planes which is not uncommon.

Really minor thing: The chip most likely has no gold bonding wires anywhere in it. It's likely a flip-chip package, where there's a grid of teeny tiny BGA pads on the die itself, which get soldered to the substrate. After that, they usually get some sort of epoxy or other strain relief flowed between the die and the substrate to act as a strain relief. Finally, the chip gets the heat spreader put on, the substrate is balled, and then it's (eventually) soldered to the PCB. Fascinating stuff!

Been doing electronics design for years now, and it's kinda crazy all the steps you gotta take to get those pci-e lanes to behave under the worst conditions, but it's also crazy just how much wiggle room you get too. I know people were using just plain bodge wire on the pi4 back when it was first discovered to have pci-e, and interestingly pci-e even has support for flipping the wires of a pair, despite them being polarized.
Also, Ethernet magnetics are fascinating. My understanding is that the original intent was to deal with ground differentials, where the ground potential of a circuit could be 1000's of volts above the ground of another circuit. The PoE is a clever hack that uses the fact that you're basically scrubbing the voltage potential from the lines with the magnetics, meaning you can put whatever voltage difference you want across those lines. I know most poe uses either 24v for passive or 48v for active, but those voltages were mostly selected due to restrictions on high voltage lines in buildings (or at least that's my current understanding of it. Only source I have is friend who has been designing network circuits a decade longer than I have.). by sticking with 48v, it counts as low voltage, and in the majority of states, means it can be self-installed.

My monitor sent me electromagnetic radiation to transmit information about Jeff's new video to my eyes.
I call these frequencies of electromagnetic radition, JG rays.

Actually differential pairs are not length matched, they're time matched. The time delay between the pair of lines should be as small as possible.

I worked as Service Engineer for Nikon Metrology for 2 years. It reminds me of the old time scanning my iPhone and using the picture as background or looking on the PCB of NeoGeo Pocket Color cartridges. It's nice to see this kind of technology explained and detailed for everyone.

You'll never catch me, Jeff. *furiously scratches away at hidden antenna traces*

Very cool view of our electronics.. Thanks Jeff!

3:36 - the lattice pattern is a PCB layout feature (here the PCB being the chip package substrate). This "in-fill" is made that way for multiple purposes - too little copper would mean that the compression of the substrate during lamination would not be even, too much copper would make an asymmetric weight while electroplating the vias, and also large empty or full areas are making issues during etching. So designers choose some sort of infill.. you can see either a diamond shape mesh, or little rectangles placed at otherwise empty areas, even on outside of the PCBs.

The basic idea of a buck converter is pretty simple. It switches between two states, in one state the inductor charges in series with the load, in the other state the inductor discharges into the load. The capacitors act to smooth out the current drawn from the supply and the voltage delivered to the load. This allows the voltage to be reduced while keeping wasted power to a minimum. The output voltage is regulated by varying the duty cycle of the switching.
A multi phase buck converter just has more than one inductor which switch at different times which gives a smoother and more stable result.
You can't put big inductors or capacitors on an IC, hence why you see the pattern with the PMIC chip in the middle with the control logic and switching elements for a bunch of buck converters and then a bunch of Inductors and Capacitors surrounding it.

Have you seen CuriousMarc's video on 3D x-raying some apollo gear? It's absolutely fascinating!

I design ICs for DC-DC converters for a living (major semiconductor manufacturer). That power delivery isn't mainly so different parts can quickly turn on and off. It's because these big SOCs have a bunch of rails (power supply nets) and need a fairly complicated PMIC (power management IC) to deliver power to all those rails and properly sequence all those rails at power up. Most of those inductors are for different channels of a bunch of buck converters (take higher voltage and step it down). See, you power a Raspberry PI with 5V. But no even remotely modern logic chips run on 5V. So, you gotta step the voltage down. And different parts of the chip want different rails. For example, the core logic probably want it's own rail, the DDR interface wants another, the IO another, etc.
DC-DC converters and inductors seem complicated, but they're actually pretty simple. The way to think about inductors is they are the opposite of a capacitor. If you have an ideal capacitor and you try to change it's voltage, you need a certain amount of current for a certain amount of time. Inductors are like that, except for current. So, if you have an inductor doing a certain amount of current, it takes a certain difference in voltage across that inductor for a certain amount of time to change it's current. So, what you can do is charge an inductor up, then, since you're "storing current" you can discharge that current into a load in some controlled way to make an output at a different voltage than the input. You may have heard how you need suppression diodes for relays. That's because the coil of a relay is very inductive. When the relay is on, you're doing current through that inductor. When you turn it off, all that current needs to go somewhere. If you don't give it a controlled place to go, it will spike the voltage to something potentially dangerous for the electronics. So, the suppression diodes give it somewhere to go. We use inductors in similar ways to make all sorts of output voltages from input voltages. The output can be higher, lower, or inverted (and of magnitude greater than or less than) the input, depending on how we arrange things.
Another way to think about a buck converter is imagine you have a series of pulses. If the pulses were high 100% of the time, the average would be just whatever the high voltage is. If it were low 100% of the time, the average would be whatever the low voltage is. So, if you make the high time some other fraction, you can make an average somewhere in between. Then, all you need is a lowpass filter to make DC rather than pulse train. Since it would be very inefficient to do that with an RC filter, you can use an LC filter to do it with much less loss.

Wait until some phone case company screenshots the thumbnail and crops it to use the X-Ray picture

Not sure if the components on the differential data lines to the memory are capacitors.
Quite often you see resistors in series with communication lines to reduce 'ringing'.
Right now AlphaPhoenix has on both his channels some very (!!) good videos about impedance and he also briefly mentions this aspect in his (really) excellent talk.
I highly suggest you'll look at those and also the first few comments as those are also a great addition to this.
Anyway it is really great to see these boards X-rayed, so keep up the good work, Jeff.

As is often the case, thanks Jeff for doing these things so the rest of us don’t have to. This certainly helps to emphasise what impressive pieces of engineering these little SBCs are.

I have been doing hobby PCB design for years, even dabbling into PCIe and other high speed protocols.
Length matching is important in very high frequency applications, because if not length matched, some signals can literally arrive faster than the others, and then the data won't make any sense. Length matching by curling, as you've said, has it's own caviats, because they essentially act like antennae, so you need to be very careful where you route them (away from any analog signals, or other high speed traces, due to crosstalk), and ensure proper EMI insulation.
Decoupling caps for power rails are there to smooth out any voltage spikes or dips, that can occur for example due to external EMI, non-ideal power supply or a billion other things. The coupling caps on the high speed rails on the other hand are to remove DC offset, that is unduced while measuring the voltage difference between those pairs (amongst other things).
Regarding the size of IC dies and their packages - I'm sure you at some point have encountered a weird black blob on a PCB with traces leading to it. Those blobs are basically IC dies soldered directly to the PCB, without package. Their advantage is that they are super super small compared to packaged ones, their biggest downside is, that they are extremely fragile in that state (that's why they put that black goo over them, which is kind of the same plastic as the plastic IC package material). They are also much harder to route (and manufacture the PCB) since the "pins" are much, much smaller and closer together.
On the power deliery, they use both inductors (L) and capacitors (C) (with other components) to form a charge pump, which is used to convert voltage (from higher to lower and vice versa), as well as LC filters to filter out any noise from switching power supplies (that most often operates at 125kHz, and some components, especially those that deal with high speeds or analog signals, doesn't like that).

The lattice structure is traces on different layers going from the memory to the SOC. It is common practice to not run traces parallel on different layers to minimize their capacitive coupling. The serpentine wires are also not just for differential pairs. Any time you have high speed data the length matching can ensure that multiple data paths will reach the chip at the same time, so it is easier to sync data transitions with the chip clock.

Game Theory pun made me chuckle. I was not aware that some ethernet jacks have the filtering built in. Very cool.

this is really cool to see in such high detail!

You know what they say on EEVbog,
Don't turn it on !
X-ray it apart !
On serious note i wish Dave took a look at it on a video.

I LOVE IT JEFF, I was like, Whats on my screen, Wait...Jeff is watermarking so they don't "right click" or "screenshot" his x-ray, LOVE IT! Good move sir!

Jeff is quoted as saying "... but I'm no engineer." Even though that may be true from a profession standpoint, I think your breadth of knowledge more than qualifies you as an intellectual equivalent. I call 'em as I see 'em.

Those micro HDMI ports look so happy to be here.

One of the greatest features of DICOM I personally like - is an ability to precisely measure distances. In this case, you can measure all components and distances between its pins without disassembly or desoldering. What a great way for reverse-engineering! For some reason, not many doctors in my area are happy with this idea😅

Mighty mite that RPi5. I seldom stop to look at its innards but it's worthy of admiration for the resourcefulness of its designers. Very informative video as usual.

I can see how this tech can be used in advanced imaging and computer designs, Great Explanation.👍👍

Dr Jeff do you warm up your stethoscope before you place it on the Pi? 😂!
Thanks for video and showing all the secrets of the Pi, even Redshirt Jeff is Green with envy.
Have a great day!

Love it Jeff. We're featuring it on the Raspberry Pi blog tomorrow and we've got a reaction quote from the engineer who designed Pi 5!

If we see a Casetify Raspberry Pi 5 X-ray skin, we'll know where they -got- stole it xD

How many layers is the PCB?
Edit: and you said it a bit more in the vid lol. Awesome job!! Your channel has fast become my fav. Love the engineering channel too! Your dad is awesome and love the stories.

What a cool look at the Pi, great work Jeff. And that's some awesome merch!

Cool! Really amazing! Lots of smart people. I'm always amazed at the complexity underneath what we regularly use and think of as normal.

The fact that the Pi is only 6 layers is pretty impressive especially given how complex that SoC is. My own hobbyist PCB designs are sometimes 8 layers! Then again, they do seem to use blind/buried vias, that definitely makes it easier

Hey Jeff, great video! The Xray and wonderful explanation made for a fantastic experience. You have a skill for explanation in a clean and concise way and you keep it light and entertaining!
I’m not an rf engineer but I *think* the PCB based antenna, triangular ground plane cutout is a form of a waveguide. I could be totally wrong. 😂 Definitely interested in antenna design and it sounds like I need to read some more on it.

13:01 it is true, you can learn so much just from changing perspective.

I wish you had used a BIG cursor in contrasting color to highlight everything you discussed. The tiny white dot was mostly invisible and impossible to follow on screen.

4:58
insert *I understood that reference* meme

The caps beneath the SoC are most likely not some sort of filter caps, to filter out noise, which is spread to other components. Instead, they store power that is needed by the SoC during dynamic processes and deliver it via the shorted path possible. You are not mainly wrong, because this also results in better EMI performances, but the main reason they are placed there is to provide a bypass path for transient currents ...

Amazing video Jeff. Love it!

9:35 the happiest micro hdmi connectors I've ever seen

I think this is the first video where i needed more than 720p to watch properly

I don’t know how possible it would be, but if you could get some of your tshirt designs on some LTT shirts, they are super comfy and I definitely would be purchasing one!

Jeff, much respect to you. I am a EE flunkie (finished Comp Sci) so I had quite a bit of the EE curriculum (sadly I just didn't get the "official credentials" like those that hold the EE piece of paper). Your grasp of circuits and electronics amazes me! My understanding is you started in tech as a web developer (like front ends and UX web developer). I'm respectfully jealous of how much knowledge you have amassed on your own! Custom compiling linux kernels, studying circuit board layouts, etc... What's your secret? (I'm guessing probably just a 200 IQ). Always a fan and hats off to you man!

Really cool video, Jeff!

Differential data is sent as a pair of voltages, one normal, the other is inverted. This improves noise immunity.

This was waaaay over the top of my head. But I can imagine this would be super interesting for all the people in the field that understand this!

All this complexity.... In a computer that is sub $100 USD.... looking at this tiny stuff really makes you appreciate AMD's Threadripper...

This is amazing! I want a phone case with the x-ray images of RPi 5

this was awesome to watch while holding and comparing the xray to a pi 5 in person

Capacitors block DC because once they fully charge, they stop charging and both sides stop moving current if the voltage doesn't change.
Inductors are the opposite, they are DC shorts but block AC (once frequencies go high enough for the particular inductor).

Fascinating! Thank you!

And that's just a theo-, JeffPat? Do I see cans of diet coke and notebooks of restaurant history details?
In all seriousness, I really enjoyed this video. The more we understand how these things interconnect and work, the more we can pull crazy ideas through them.

This brings up a good subject. It would be great to see SBC SoCs with memory on them. Would greatly simplify the boards.

I love that Game Theory reference :). Nice video. Maybe I will buy a Pi 5 if it is in stock localy.

I'd love to have one of those x-ray images on a metal print for my office wall!

Thanks for adding actual captions for the Deaf.

"Thanks Crohn's"... I feel noticed! ❤ Hope things are going well for you Jeff!

Very fun! Thanks!

Great photo for the thumbnail

I want to zoom through those edge-on views of the board like a sky taxi in The FifthElement! There’s an AI that can do that ...

Really loved that Game Theory reference right there 😂

Awesome video!

Great video!
I think you misuse the word 'bonding wire'. I don't think the SoC uses bonding wires but rather is a 'flip-chip' that has the C4 balls connect to the package, that uses larger solder balls to connect to the PCB. Bonding wires are used for chips that have only 10 .. 20 I/O's

Nice! I spent my PhD working on ways to improve the contrast resolution of micro-CT scans using research machines based on Nikon Metrology's scanners (looking for extremely small changes in mineral density in anything from extracted teeth to rolled-up parchment scrolls.) My postdoc friend started X-raying his food after finding a worm in his lunchtime apple one day.

The epic dialog in this video is at 08:03 "I wouldn't recommend it"

Fascinating! 🧑‍🔬

Capacitor are use to remove DC offset because their output voltage depend of the change in voltage input (and the frequencies of the change to choose the capacitor value), not the absolute value of the input.
Same principal is used in audio amplifier output, specially class A where you have only one transistor working only on a positive rail.
With no signal, you output a DC signal around half the voltage (the offset), capacitor block DC ( and continuous signal will blow your amp). When the output go over or under the offset voltage, the capacitor will reproduce the same variation around the ground.
In digital, the capacitor is used for decoupling the signal from any offset present in the signal ( aka ground noise ) on a high frequency low voltage binary signal.

The power Management Integrated Circuit "PMIC" is a highly efficient switch mode power supply with minimal losses to provide all the voltages needed by the Pi from a single voltage supply.
The capacitors assembled on the main Pi's Chip known as System on Chip "SoC " are for decoupling.

Dr. Geerling Pi D. is in the house!

MIND-BENDINGLY EYE-OPENING!!!!! lol
I was having a REALLY hard time seeing the things you were pointing out... I had to either increase or decrease my video cards video brightness (it only adjust the brightness of video playback, and not the rest of the screen or 3d rendered stuff like games!! I just discovered it on my AMD 6650XT in the AMD Adrenaline app under Audio & Video... it's been useful and I'm telling everyone about it lol) I was able to adjust it and see everything really well, but it would have been impossible to watch this without making any adjustments.....
I wonder if this has to do with the YT stream, or my TV's settings (yes I'm using a 50" 4K TV as my computer screen.... but I sit about 7 feet away lol) .. I think it's the stream because everything else looks great, but I am CONSTANTLY having to adjust it when I watch CZcams... which I do pretty much 24/7 lol ..... - I wonder if everyone else was able to see the different parts you pointed out just fine.... hrmmm I think HDR also has to do with this too.... which I have turned on in Windows
- Maybe I should watch it again on my actual computer monitor... it's only 34" 1440p but it's got a 165hz refresh rate.. but I never use it really....
- - -Why am I tell you all this?? i have no idea!! LOL That was a really cool video tho Jeff!!! THANK YOU!!! :D

Hi Jeff, awesome video! 👍👍 The RAM lines being a mixture of bent/squiggly/straight is to get their electrical length, for signal timing, to within the required tolerances for maximum transfer speeds.

I'm wondering if it's possible to enable PCIe bifurcation. In this case it could make sense to cut 3 of the 4 lanes that go to RP1, and reuse them to connect other devices.

Important for safety critical & secure components!

Now this is what the deep dive of this Raspberry Pi…

It's cute that you have access to a raspberry pi at all. you have more than my country has.

Just don't use the image to design a "transparent" case only to have it ripped off by a competitor who you now have to sue for big bucks. Not that that would ever happen to a company who makes iPhone cases. 😂

inductors are there to resist the buildup of current, the mechanical analog of electric circuits known as "spintronics" uses some weights on arms instead, using momentum. they essentially are surge-protectors, so that something doesn't go from 0 to 100 amps [exaggeration] in an instant, and instead winds up from 0 to 100 in a bit less of an instant.

The squiggly lines you're talking about are traces, it depends on what the engineer intends, some are set that way as delay lines and some are uses as antenna array or in some cases used as a RF balancing circuit (this one is pretty rare and hard to accomplish). Sometimes the line delays are a way to avoid crosstalk from other layers but there are better ways to do that, too.

would you make a video ab what makes the pi5 better for taking pictures/videos?

Hey Jeff,
I'd love to see what's inside the large BGA packages. You might wanna try lapping the layers off and a using a microscope for some lovely die shots!
It would look awesome on a T shirt aas well.

Love the Jeff Geerling watermark. Afraid of being Castefied? ;-)

How much does imaging a board like this, as well as the associated data processing, cost in USD?

The reason for ethenet being transformer-coupled, is primarily because long runs between places can have quite different ideas what 'ground' is. And the differential inputs for differential logic signals only works properly if the 'common mode' voltage the two signals are floating on, is small enough to still allow the differencing amplfier to still 'take the difference'. Practical differencing amplifiers like this have a limited range over which they can accept signals whilst still working right, so a big enough common-mode on both wires can cause it to no longer be able to function.
So, you break all the ground loops by just transformer-coupling your digital signals.
And later, some bright spark realises that, if you're going to do that anyway, why not deliver DC power as common-mode DC? And PoE is born. Which works basically by avoiding a ground connection for the thing hanging out on the end of the run, powered by PoE. It can work fine with a big DC offset there, and it's ok.
But this does mean you need transformers to physically connect 1xBaseT ethernet. (it's what the 'T' is for, right?). Building them into the port itself has made a lot of sense for a long while. But to send/receive data, you need a chip designed to handle the bipolar (ie, both positive and negative voltage, and so both-possible direction current) pulses that go through the transformers. And this is mostly what the PHY (often built into the MAC) chip does.

Osteoporosis and crohns best friends forever. My hips are killing me. Thanks for the distraction

i think you are safe from the fcc because as long as you stay within the frequency ranges of the wifi there should not be any problem.

This makes me want to play Factorio.

When you say the I/O chip was made bigger so you wouldn't short out things by touching the GPIO pins, do you mean that they added protections against ESD and overcurrent to those pins?

that lattice in the memory chips is most likely a grounded shield. some people have sanded through potted usb drives and sd cards often to recover data. and they grind through a top copper layer first. the lattice is used to use less copper than a full copper shield. in theory you can even measure the size of the holes to calculate the smallest wavelength it can protect against.

9:07 The key use of inductors is to efficiently convert between voltage and current. Without them you're left with dissipating excess voltage as heat (linear regulator), or using a much larger traditional transformer.

If Jeff spoke with a southern Alabama accent then he would be Destin from Smarter Everyday. Good video Jeff

dbrand x Geerling collab confirmed!!111

Some people design a board, and some look what the incredible work they did.

A PCIExpress Theory....LOL!!!!!

Correct me if I am wrong but are x rays technically ionizing radiation? And isn't that harmful to electronics? It's just a question. I think it doesn't affect it that much because there is some form of RAD hardening done and x rays aren't as bad as gamma and beta (penetrating)

I always thought you had to be an engineer as you are quite knowledgeable overall