Just gotta say, as someone who has gone through the universities and then into the industry. Your channel is probably the best channel for getting REAL practical application and useful knowledge for PCB design and I love how you present the simulations and use the extremes to show a point (i.e no via used vs the via fence - via fence not likely being realistic for an actual design I suspect but nonetheless proves the point quite fantastically). Appreciate what you do.
Wow, this just blew my mind!! I already knew and understood why you need stitching vias. But seeing it this way is just sooo interesting! It makes everything visually clear and straightforward. Thank you for this great simulation videos, you helped me a lot!!!
I just stumbled on this video, two years after you made it. Better late than never! Great video. I didn't expect the huge improvement from the GND via fence, so it was very educational! Thanks!
Great video! Also I think that it is interesting to add that in a four layer stackup TOP-GND-VCC-BOT if you have a critical signal over top and you must go to bottom, then the stitching via to gnd is not what you need. A capacitor VCC-GND close to the via will do the magic. You must consider that the polygon of the VCC net in VCC plane (poly because more than one voltage is ussualy needed so the plane has cuts) is over the portion of the track on bottom. I propose a simulation of this case for a future video. Best regards!
@Digital Nomad If you have two or three different supply voltages your VCC layer is not a solid plane, therefor can't be used as a return plane for signals on the bottom layer. Therefor I put the signals on layer 3 and put the power distribution on the bottom layer. Other option is go for a 6 layer board.
Your videos about PCB design are just amazing! I have watched most of your Altium tutorials and they were super helpfull. Thank you so much for your great work. I really appreciate it.
Almost every single video of yours, there is something new to learn.. great work Robert, not many schools teach these.. I really like insights derived from your talk with Eric Bogatin and Rick Hartley
Thanks for this. It's a very concise reference to point to, and makes what is technically complicated easy to understand. Not everyone has access to ADS, so I really appreciate this sort of content.
As always video was full of information, and today I learned something new about return currents because of you so thanks a lot. Keep sharing videos like this.
Try the coplanar waveguide (your fence) with minimal vias. This is typically how a coplanar waveguide is done and it would be interesting to compare the results.
You may also want to investigate how multiple GND/PWR VIAs on decoupling capacitors impacts their effectiveness. Also, capacitor physical size. Great series of videos, thanks.
Could you do an example with some serial bus standards? Like SPI or SD for example, I'd like to see how the traces intefere with each other. Great video Robert!
The simulation where you placed those ground tracks to completely shield the signal track is really cool. I remember when I was measuring cross talk between sensitive analog signals on an eeg amplifier, my senior engineer told me that if we use this trick in layout then the cross talk between adjacent channels will be close to 0. Thanks for showing me how that really looks like 👍.
Great video! I would be interested to see simulations of different frequency signals and how the spacing of the stitching via effects the stray currents for the different wavelengths.
Your recent few videos have been very eye opening (pun intended). I always learned what to do from other sources but this is the first time I'm seeing exactly why. Thank you for this series :)
@@RobertFeranec I would be interested in seeing different current strengths too, since it is both frequency and current that define how big of a mess it will be
Thank you Robert for the great video. Could you do a video on impact of sandwiched signal (perfect strip line ) model VS one side Ground and other side split plane signal ? Thanks in advance
Roberto, muchas gracias por el video, muy interesante, y simple, no necesitas saber más, una via cerca bien, 6 talvez para cosas muy muy especiales. Me quedo con eso. Saludos y gracias!!! te vemos desde LATAM también. Disculpen el comentario en español pero DOMINAREMOS el mundo no dentro de mucho, solo tenemos que resolver algunos temillas internos. jejejeje
Thanks Robert, visualization is always great, exceptionally the last slide that compare all of them. Other people have suggest great things to try. 18min is also good length.
Thank you a lot for that Video and the effort you are puting into it. At the moment this is my most favorit UA-cam content and im looking everyday if something new was uploaded
I think the reason for return currents to flow in other reference layers as well is due to the impedance of the return path. The reference plane directly under the signal will have the lowest impedance return path. But the subsequent reference planes will also have a return path impedance which is finite. The value of each return path is a function of frequency, dielectric height from the signal layer (as height increases, impedance increases) as well as the dielectric properties of the material and transmission line dimensions. You can think of each reference plane return path as parallel connected resistors (current is shared between resistors, but lower resistance values conduct more current). The first reference plane being Z1, the next being Z2 etc. So |Z1|
Thanks Robert for the video. What I knew about these vias is that Altium has a tool called Vias Shielding, which allows you to create a track surrounded by vias so that it improves its characteristics. Greetings from Chile
More, than 10 years ago, when i worked on military factory, old womens, which work's in P-CAD spoke me about that thing. They didnt have SIpro, only P-CAD and own soviet expirience in electronics. Today I started to respect them even more.
Thank you for the wonderful simulation. just wondering, if you had done the same simulations with 1Hz signal or way upto 1GHz signal! if yes could you share the comparative slide? thanks for the share
Adding the ground fence does add a lot of distributed capacitance, in turn affecting the input impedance of the line. That change in impedance will change how the input signal couples into the line. The channel host can correct me here, but ADS’s ports are probably set to be matched, so the input power was consistent in the two the simulation. Also, at 1MHz the change is probably small, but the simulation could easily give us that change in Zin.
The current penetrating to lower layer is probably visible this much because the color scale is saturated strongly in the upper layer. To see all values you could try logarithmic scale. I would be curious what is the actual ratio between the return current (density) on 1st and 2nd GND layer.
love your content . you should do one on how to handle a separate digital and analog ground planes. Such as where to attatch them, should it be close to source or close to a sensor? what if you only have a single layer board (without a ground plane)
In a good design there is no reason for different "types" of ground planes (e.g. "digital", "analog") other than for galvanic isolation. See works of Keith Armstrong (e.g. www.emcstandards.co.uk/files/part_4_planes_corrected_29_june_17.pdf)
As far as I see at 4:50, you use an ideal source and 1 Meg sink for the simulations and also again it looks like you didn't calculate impedance for all 3 conditions (top to bottom, top to L3 and coplanar trace). What do you think that how those (impedance mismatches) effect the current density?
You deserve big respect. I got a question. You simulated only with ground planes but what about power planes? Can you share more simulations including power planes and ground pour at top layer?
Congrats, very nice video, thanks a lot for sharing, just to clarify; it seems the worst case is when you have the stitching via far away of the track transition, seems to be worst than the case without stitching via.
Great series, Robert. It helped clarify a lot why some practices are done. In case you'd like to work on it, you seem to be pronouncing "Analysis" the same as "Analyzes" rather than /əˈnalɪsɪs/ .
Thank you for your nice video! Can you please how to import the PCB layout of Altium to Keysight ADS? I want to check my own PCB layouts with regard to the current path. And one more question! What is the difference between Ansys and Keysight ADS?
Very informative video. Really learnt a lot. I think you can avoid the return currents in the other ground planes be adding stitching via along the length of the trace and not just at the point of transition.
Can you please share the process with which you were able to import the design from Altium into Keysight's ADS software and how you started the solution? Please this would be really helpful as I need to simulate some Mixed signal boards I designed.
Great videos, should see how those return currents affect cross-talk between lines. Even if two signal lines are well spaced, can a badly spread out ground current add noise? Can limiting the ground currents reduce EMI? Obviously, but how many vias will it take? A fun example, but something we should never do, would be a pwm signal next to an important analog signal line.
I was rewatching this video now after watching your call with Rick Hartley, and I was wondering if you have the through hole connector connected to all planes or just the top signal and ground plane?
Great simulation, thank you. Here is a question in my mind. Let's think it is a four layer system. Signal, Ground, Power, and Signal. How does the return signal look, and what are the possible solutions?
The return current is like a displacement current as well so depending on the distance between layers which can define the capacitance between the layers, the return current can flow on layer 2 gnd plane and layer 4 gnd plane when crossing signals from layer 1 to layer 3.
Great video Robert. What if the board is dissaminated with stiching vias? I know that Altium Designer has a feature to add stiching vias on all the board. Do you advise this kind of layout? And last: what's the difference between stiching vias and shielding vias? Thank you again
Appreciate your sharing. I'm curious about if the frequency up to 1 GHz and 10 GHz, does it still need so many stitching via to control the return current?
@@vejymonsta3006 I have not tried to simulate so high frequencies yet. I asked Keysight if I could play with their RF 3D field simulator ... lets see how it goes
I wanted to see the last one without so many vias, because I think that the ground tracks on the same layer also were a improvement and would like to see it without so many vias only some at start end and middle maybe
I think it makes sense that you see the currents following the tracks on the adjacent layers. The energy exists in the field between the signal trace and the reference plane, and that field is going to radiate outward a little - it won't be perfectly contained within the dielectric between layers.
Finally real simulations / answers from someone who designs real world PCB's! Thanks!
Thank you very much Danny
Just gotta say, as someone who has gone through the universities and then into the industry. Your channel is probably the best channel for getting REAL practical application and useful knowledge for PCB design and I love how you present the simulations and use the extremes to show a point (i.e no via used vs the via fence - via fence not likely being realistic for an actual design I suspect but nonetheless proves the point quite fantastically). Appreciate what you do.
Thank you very much
You manage to clarify concepts that other people seem determined to obscure. Well done. Thanks!
Thank you C B
Wow, this just blew my mind!! I already knew and understood why you need stitching vias. But seeing it this way is just sooo interesting! It makes everything visually clear and straightforward. Thank you for this great simulation videos, you helped me a lot!!!
Thank you
I just stumbled on this video, two years after you made it. Better late than never! Great video. I didn't expect the huge improvement from the GND via fence, so it was very educational! Thanks!
Great video!
Also I think that it is interesting to add that in a four layer stackup TOP-GND-VCC-BOT if you have a critical signal over top and you must go to bottom, then the stitching via to gnd is not what you need. A capacitor VCC-GND close to the via will do the magic. You must consider that the polygon of the VCC net in VCC plane (poly because more than one voltage is ussualy needed so the plane has cuts) is over the portion of the track on bottom. I propose a simulation of this case for a future video. Best regards!
Thank you Santi. PS: I have this on my list to simulate it. Some other people also would like to see it.
TOP - GND - SIG - PWR is my preferred setup, normally have more than one VCC
@Digital Nomad If you have two or three different supply voltages your VCC layer is not a solid plane, therefor can't be used as a return plane for signals on the bottom layer. Therefor I put the signals on layer 3 and put the power distribution on the bottom layer. Other option is go for a 6 layer board.
@@sparqqling L1 and L2 are close together, however L2 and L3 have generally more than 1mm prepreg inbetween
@@RobertFeranec I am looking forward to this “with 4 eyes” 👀
Your videos about PCB design are just amazing! I have watched most of your Altium tutorials and they were super helpfull. Thank you so much for your great work. I really appreciate it.
Almost every single video of yours, there is something new to learn.. great work Robert, not many schools teach these.. I really like insights derived from your talk with Eric Bogatin and Rick Hartley
Thank you Srudeep
Thanks for this. It's a very concise reference to point to, and makes what is technically complicated easy to understand. Not everyone has access to ADS, so I really appreciate this sort of content.
Thank you very much VejyMonsta
gnd via fence is called grounded coplanar waveguide. It's used a lot in RF designs
As always video was full of information, and today I learned something new about return currents because of you so thanks a lot. Keep sharing videos like this.
Thank you Robert for simple lunguage explanation! The latest simulation shows like you fence the signal like in coaxial cable.
Try the coplanar waveguide (your fence) with minimal vias. This is typically how a coplanar waveguide is done and it would be interesting to compare the results.
1/10 lambda spacing would be plenty enough. The amount of vias he used is a bit of over kill for the simulated 10k ~ 300M frequencies
Hello Sir, Could you make the same for differential pair signals..
Very important and wonderful video, thank you very much.
You may also want to investigate how multiple GND/PWR VIAs on decoupling capacitors impacts their effectiveness. Also, capacitor physical size. Great series of videos, thanks.
Thank you so much. This is exactly what I am looking for. I was wondering how a guard ring for rf pcb works. But I understand how it work visually.
Wonderful video Robert. Return path is so important as you said and most of us do not consider it. Thanks a lot. Share a lot.
Big thumbs up! Very interesting video. I really enjoy these real life examples, explained in a way I can understand. You're a good teacher!
Thank you very much.
Great work as usual Robert! Thoroughly enjoy those videos
Thank you very much Bannay
very good simulation, nice and clean.
I really appreciate that you addressed the topic I suggested some time ago. Kudos!
Thank you Lukas
Wow robert. It is always such a treat to watch your videos... Thanks you.and please continue and inspire us more.
Could you do an example with some serial bus standards? Like SPI or SD for example, I'd like to see how the traces intefere with each other. Great video Robert!
Excellent explanation. Thank you.
The simulation where you placed those ground tracks to completely shield the signal track is really cool. I remember when I was measuring cross talk between sensitive analog signals on an eeg amplifier, my senior engineer told me that if we use this trick in layout then the cross talk between adjacent channels will be close to 0. Thanks for showing me how that really looks like 👍.
Thank you Nihar
Great video! Thanks for serving this tremendously useful knowledge on a platter!
Great video! I would be interested to see simulations of different frequency signals and how the spacing of the stitching via effects the stray currents for the different wavelengths.
Best explanation, appreciate your efforts
Your recent few videos have been very eye opening (pun intended). I always learned what to do from other sources but this is the first time I'm seeing exactly why. Thank you for this series :)
Thank you very much PS: It's the same for me ... that is why I am creating these videos
Like to see different freq down the 0mhz.
Good idea. I am making a note, I can try that in some future videos.
Agreed, seeing how various frequencies compare would be really interesting. Thank you for your videos Robert! They really are enlightening!
@@RobertFeranec I would be interested in seeing different current strengths too, since it is both frequency and current that define how big of a mess it will be
Thank you Robert for the great video. Could you do a video on impact of sandwiched signal (perfect strip line ) model VS one side Ground and other side split plane signal ? Thanks in advance
Very simple and good explanation! Thanks a lot, Robert
Roberto, muchas gracias por el video, muy interesante, y simple, no necesitas saber más, una via cerca bien, 6 talvez para cosas muy muy especiales. Me quedo con eso.
Saludos y gracias!!! te vemos desde LATAM también.
Disculpen el comentario en español pero DOMINAREMOS el mundo no dentro de mucho, solo tenemos que resolver algunos temillas internos. jejejeje
Thanks Robert, visualization is always great, exceptionally the last slide that compare all of them. Other people have suggest great things to try. 18min is also good length.
Thanks Robert, a very instructive video.
What is the program do you use for this simulation?
Always best videos. Thank you again. I learn always with your videos.
Thank you very much Freddy
great! It's easy to understand. I'll use many stitching VIAS.
Thank you
very informative, especially the chart at the end!
Another very informative simulation -- thanks Robert!
Thank you Graham
Thank you a lot for that Video and the effort you are puting into it.
At the moment this is my most favorit UA-cam content and im looking everyday if something new was uploaded
Thank you very much white test for very nice words
Thanks for this simulation it is really useful
This video is so helpful. Thank you!
I think the reason for return currents to flow in other reference layers as well is due to the impedance of the return path. The reference plane directly under the signal will have the lowest impedance return path. But the subsequent reference planes will also have a return path impedance which is finite. The value of each return path is a function of frequency, dielectric height from the signal layer (as height increases, impedance increases) as well as the dielectric properties of the material and transmission line dimensions. You can think of each reference plane return path as parallel connected resistors (current is shared between resistors, but lower resistance values conduct more current). The first reference plane being Z1, the next being Z2 etc. So |Z1|
Thanks Robert for the video. What I knew about these vias is that Altium has a tool called Vias Shielding, which allows you to create a track surrounded by vias so that it improves its characteristics. Greetings from Chile
Thank you Leonardo
More, than 10 years ago, when i worked on military factory, old womens, which work's in P-CAD spoke me about that thing. They didnt have SIpro, only P-CAD and own soviet expirience in electronics. Today I started to respect them even more.
Thank you so much,Robert It's very useful.
Another useful video, as usual, your videos always make to learn something new sir, thanks for sharing your knowledge.
Thank you Haribabu
Thank you for the wonderful simulation.
just wondering, if you had done the same simulations with 1Hz signal or way upto 1GHz signal! if yes could you share the comparative slide?
thanks for the share
The fence reminds me of a coaxial cable. Does it add capacitance that affects the signal? BTW thanks very much for these videos.
Thank you Roger
I would have to imagine so, you could see that those ground traces next to it in the final example had a ton of current flowing through them
Adding the ground fence does add a lot of distributed capacitance, in turn affecting the input impedance of the line. That change in impedance will change how the input signal couples into the line. The channel host can correct me here, but ADS’s ports are probably set to be matched, so the input power was consistent in the two the simulation. Also, at 1MHz the change is probably small, but the simulation could easily give us that change in Zin.
Really enjoying your vids. Thanks!
Thank you Oguzhan
Thank you for this video.
The current penetrating to lower layer is probably visible this much because the color scale is saturated strongly in the upper layer. To see all values you could try logarithmic scale. I would be curious what is the actual ratio between the return current (density) on 1st and 2nd GND layer.
love your content . you should do one on how to handle a separate digital and analog ground planes. Such as where to attatch them, should it be close to source or close to a sensor? what if you only have a single layer board (without a ground plane)
In a good design there is no reason for different "types" of ground planes (e.g. "digital", "analog") other than for galvanic isolation. See works of Keith Armstrong (e.g. www.emcstandards.co.uk/files/part_4_planes_corrected_29_june_17.pdf)
As far as I see at 4:50, you use an ideal source and 1 Meg sink for the simulations and also again it looks like you didn't calculate impedance for all 3 conditions (top to bottom, top to L3 and coplanar trace). What do you think that how those (impedance mismatches) effect the current density?
I found my new wall calendar's picture... (The one at the end of video !) Thank you a lot Robert
:)
I'd like to see a continuation of this video, where you sweep or step the frequency from VLF to SHF bands. If that's possible in ADS anyway.
You deserve big respect. I got a question. You simulated only with ground planes but what about power planes? Can you share more simulations including power planes and ground pour at top layer?
Thank you!
Well done!
Great video! It might be interesting to see this with a differential pair.
Very good idea. I made a note about this. Thank you
Congrats, very nice video, thanks a lot for sharing, just to clarify; it seems the worst case is when you have the stitching via far away of the track transition, seems to be worst than the case without stitching via.
Great series, Robert. It helped clarify a lot why some practices are done.
In case you'd like to work on it, you seem to be pronouncing "Analysis" the same as "Analyzes" rather than /əˈnalɪsɪs/
.
Thank you very much Tom
Thanks for the Video!
Thank you
Very interesting thank you Robert
Thank you Gharbi
Great video!
Thank you a lot
This was very helpful! Can you help understand how return currents are affecting performance?
Very nice to share all this with us, Thanks a lot. One question, is ground vias necessary for small signal (logic) ?
Nice Vids Very Helpfull
Real simulation explains well :)
Great job!
Thank you Yarmela
hey robert, for 13:37, it may occur because of image current. ?
Thank you for your nice video! Can you please how to import the PCB layout of Altium to Keysight ADS? I want to check my own PCB layouts with regard to the current path.
And one more question! What is the difference between Ansys and Keysight ADS?
The two ground planes above and below the track are just two capacitors in parallel so the return current of 1MHz signal is on both of them.
Great video and many thanks for sharing. It would be nice if you also simulate the cases where 1 and 3 vias on the other side of the signal track.
Very informative video. Really learnt a lot. I think you can avoid the return currents in the other ground planes be adding stitching via along the length of the trace and not just at the point of transition.
Thanks!
I didn't know this. Thank you!!
:)
Can you please share the process with which you were able to import the design from Altium into Keysight's ADS software and how you started the solution? Please this would be really helpful as I need to simulate some Mixed signal boards I designed.
Great videos, should see how those return currents affect cross-talk between lines. Even if two signal lines are well spaced, can a badly spread out ground current add noise? Can limiting the ground currents reduce EMI? Obviously, but how many vias will it take? A fun example, but something we should never do, would be a pwm signal next to an important analog signal line.
Some effects of crosstalk and coupling are visible in this simulation: ua-cam.com/video/4nEd1jTTIUQ/v-deo.html
I was rewatching this video now after watching your call with Rick Hartley, and I was wondering if you have the through hole connector connected to all planes or just the top signal and ground plane?
Excellent visual demonstration. Is there a way you could do a video on a guard trace with simulation
Enjoyed even for an ME like me.... thank you!
Thank you Joseph
Very helpful! thanks for it :)
Thank you
Thank you @Robert Feranec . I have question. how do u import your design from Altium into SIpro ADS?
Great simulation, thank you. Here is a question in my mind. Let's think it is a four layer system. Signal, Ground, Power, and Signal. How does the return signal look, and what are the possible solutions?
Your videos are very practical and have been very helpful.
I just purchased your udemy courses as well. Thank you!
The return current is like a displacement current as well so depending on the distance between layers which can define the capacitance between the layers, the return current can flow on layer 2 gnd plane and layer 4 gnd plane when crossing signals from layer 1 to layer 3.
Hi sir can you simulate curved and miterd rf trace with coplanar waveguide . Which is better
Great video Robert.
What if the board is dissaminated with stiching vias?
I know that Altium Designer has a feature to add stiching vias on all the board. Do you advise this kind of layout?
And last: what's the difference between stiching vias and shielding vias?
Thank you again
it took me a while to figure out 'written' current is actually a return current ))
Appreciate your sharing. I'm curious about if the frequency up to 1 GHz and 10 GHz, does it still need so many stitching via to control the return current?
I'm also curious what each model looks like when you sweep the frequency from VLF to SHF.
@@vejymonsta3006 I have not tried to simulate so high frequencies yet. I asked Keysight if I could play with their RF 3D field simulator ... lets see how it goes
thanks
Hello Robert
Thank you for the video!
Could you please tell me what isthe tool you are using for the simulation?
It's called ADS from Keysight
How thick is the copper and PCB material, and what is the PCB material? FR4? What frequency is the signal on the track? DC? Thanks
I wanted to see the last one without so many vias, because I think that the ground tracks on the same layer also were a improvement and would like to see it without so many vias only some at start end and middle maybe
very interesting and useful video. Could you make a video described how to insert stitching via in polygon?
I think it makes sense that you see the currents following the tracks on the adjacent layers. The energy exists in the field between the signal trace and the reference plane, and that field is going to radiate outward a little - it won't be perfectly contained within the dielectric between layers.