How to Design Your PCB Antennas And How Antennas Work (Bluetooth Antenna Examples) - with John Dunn

After finishing this video I had to check orientation of my WiFi router antennas :D

video starts: "I know some people prefer to watch short videos"
video ends: almost two hours later
xD
Robert, I prefer to watch short videos, but most of your videos got amazing content that I wish the content was 10 hours!

Thank you Robert for uploading such great content. This video was extremely helpful and look forward to more of your videos!

I have been looking for that topic for a while. You are the KING!

Incredible video!!! I was always looking for a video like this! I always wonder how a pcb antenna works.
Congrats! excellente video

Thank you John and thank you Robert!

We want more long videos ...your work is highly appreciated

This John guy is amazing, great explanation

The topic of a single antenna transmitting and receiving simultaneously at the same frequency is quite an interesting one and can give some insights about how VNA measurements actually work.
The "impedance" of an antenna is actually measured and shown (on smith) as the amount of the reflection off of the feedpoint of an antenna.
That signal can be reflected either by the antenna itself, but it can also be transmitted from the antenna, reflected off of a nearby structure, and then received again, which then shows as a slight shift in the measured impedance.
So yes, receiving a signal same like the transmitted one is manifested as a change in impedance.
And changes in impedance cause circuits to change behavior.
There is a circuit called "regenerative receiver" which is basically a weak transmitter which drastically changes its power consumption (and frequency) depending on the antenna impedance.
Hook it up in series with some headphones and it's an AM receiver. But in fact, it's a CW transmitter and can be picked up by an SDR.
Two of those in the same room can even lock their frequencies to each other.
But it's impractical to transmit and receive at the same time and band, especially when modulating both signals, since the transmitted noise would drastically desensitize the receiver.
(Just my two cents :D)

this guy always asks the right questions, I love it

Wow.. loved it. I would love to have the complete 3 hour video please. Also, waiting for 2nd part. Do have one more call with John Dunn Sir...

Ready to learn something, and appreciate all this sharing

we appreciate the work you do on this channel, good content. keep on going

Thank you Robert for this video, waiting for this topic for a long time.

I watched this trying to make sense of circuit board antennas, learned a ton of stuff, thanks.

Wow. What an amazing lecture it was. Thanks to the professor and you robert.

Robert thank you for all the amazing content you are putting out. I am especially loving these collaborations you're doing w/ knowledgeable industry pros, they're explaining concepts so simply without sparing the technical details.

That is a really interesting topic and truely a whole nother world of electronics! I would be looking forward to another video about the RF circuits John talked about!

Eagerly looking forward to the next video you do with John!

Would you mind making a video to show how to design a matching circuit and PCB layout for Chip antenna ?
Many thanks

Loved this video!

Great video! Less questions/interruptions would be better. Love to see more from John Dunn!

Excellent video Robert. It's sad to see so few subscribers for a channel producing such informative content. Keep up the good work...

Thank you very much for this video

As of this writing this is the only 1.5hr+ video I have ever watched on TH-cam. Worth it.

Thank you. Very good info

@Robert Feranec: THX for that video, it is an eye opener even to me. But either there are some misconceptions in the explaination John gave of the Inverted-F Antenna or at least I got it wrong: The BOARD itself exceeds the place where the Antenna itself goes to. The Dielectric material FR4 itself exceeds where the Antenna is. What you can see on that simulation is not where the PCB is cut down, it shows where the electrical layers go. The picture only shows that the ground plane is recessed a little from the board's outer edges for maybe 30 mm or 40 mm. And instead of the ground plane on both sides of the FR-4 material the downside copper is removed completely and the upper side copper is edged to the form of the inverted-F Antenna. It does not mean the manufacturer has to cut out the FR4 material to the form of the inverted-F Antenna. The antenna length has to be calculated to the shortening-factor of the specific material the antenna is made from. So, for FR-4 this is round about a factor of I think 0.8. Taking that into consideration this shortens the antenna to the shown round about 2.5 cm length. The radiating length is all of the outside track. You can think of it being a Tap connecting the radiating "track" to adapt the impedance. It works kind of like a tap in a transformer, moving the tap to the end of the radiator more would increase the impedance, moving it more to the ground section would make impedance going to your transmitter smaller value. And John did already explain the section being in shape of a big "C" character being kind of inductor whilest the "=" looking shaped part is a pair of capacitance plates. So they're forming some resonant L-C circuit as part of the impedance matching and adaptor part.
Me as an radio amateur sometimes got the impression that John was a little bit of unsure as well when he was explaining some details of the antenna specific stuff, but at least most of it was kind of correct. Sorry, John! But changing an asymmetric driven inverted-F antenna into a symmetric Lambda-half antenna takes a little bit more than just changing the shape of the antenna. You need matching parts, kind of "transformator" for adapting your single ended power output of the transmitter into the 2 anti-cyclic driven parts of the antenna (while part 1 of it gets positiv voltage output at a time the other one needs to get the negative one and vice versa.... ;)

You always make very nice videos :-) Robert

on last antena mismatch is because of gap, and lack of opening to transition to correct impedance. it is CPWG with Ground and it is VERY sensitive to the GAP even 0.5 mil makes huge difference in impedance thats why I would choose antena which is feed with MICROSTRIP, like previous example. MICROSTRIP is much easier to manufacture and even JLCPCB without impedance control can make it more or less reliale. I would avoid CPWG nd CPWGG completely if I go for RF.

I have taken a masters EE course in antennas, and I still learned some things more efficiently from John than that class.

Man, i have no words for those videos. I've learned so much from you!!!
I'm not even an EE, I'm a software developer but this kind of videos are so full of contend and from leaders of the field.
For me RF is absolutely pitch black magic. This was a really good introduction!

Love your videos!!!

Hello Robert. You make excellent videos about PCB design. I really enjoy and learn a lot from your videos. I think two things that are missing from your videos are High Voltage(>1kV) and/or high current (>100A) PCB designs. Keep up the good work.

Great stuff Robert!

Thanks a lot! Very useful video👍🏼

Awesome, this is really good for those of us that have never designed an intentional pcb antenna.
Perhaps in the future I would like to see as interview with someone that knows about EMI/EMC.

You might want to check the port of excitation (the signal line and ground plane), it is very likely where most of your mismatches come from because regions of it are no longer a coplanar waveguide.

Great video!

This is all fine as long as you want to use your antenna without any enclosure, and you don't care about the interactions of the rest of the PCB with the antenna. XFDTD by Remcom will pull in your entire PCB design, each layer and dielectric etc, plus the plastics and everything surrounding the antenna. Then the edges of the PIFA can be "parameterized" so that you can change the position of those edges during each sim. Over multiple runs, you then tune the length for resonance, and the impedance matching, and the whole thing converges. The resulting antenna is then adjusted in Altium, then simulated one more time to verify the changes. I've done a lot of antennas this way. My first try tripled the operating range of the device. (Given the inverse square law, that's impressive). Having your antenna impedance too far away from nominal can result in a lot of harmonics and cause you to fail compliance testing. RF current flows over your whole PCB, which interacts with the antenna and changes both the impedance and the pattern of radiation.
This is not bad, and in some cases it will be enough, but even a simple ABS enclosure will affect the tuning of the antenna. Designing as if none of the enclosure and most of the PCB is missing is not a path to dependable success.

Thank you, Robert for this video. Can make video about reflections?

Would be also nice to know about real pcb antennas matching practices using vector analyzers. And also there was shown, but not discussed, about inverted F meander antennas - what the difference to plain F? I use it in my device, got the shape from Texas datasheet, but have no theory behind it…)

Great. Thank you.

This video is very informative ,please make few more videos on PCB antennas ,if possible topics related to meander line antenna, guidelines in designing small, compact RF module , ROT.

Like this video. Please do next version of it

Robert, Thank you very much for this video , There is a lot of interesting information about RF , Please keep doing this kind of videos.
Regarding what John said that you have to play and play with the printed antenna shape to get the ideal performance then basically you can draw any random pattern and maybe you could get a very good antenna ? , Obviously taking into account the theory of lumped or distributed circuits, I mean , it doesnt have to be like an "inverted F " shape or an special shape ?

I had to design the same inverted f antenna as a project 2 months ago in my university. We've done it in ADS Momentum and the funny thing is that we find that if you have just a straight lower portion of copper, it gives a better S11. We didn't managed to get something better than -10 dB with the original design, so we started looking for a resize. So by making the low part straight and by adjusting the horizontal length of the antenna we obtained -25 dB for S11 at 2.45 GHz. In the same source, a Meandred Inverted F Antenna design was proposed, that we also had to simulate. And guess what? We didn't even nearly came to the -25 dB from the article. The best we obtained was -12 dB.
As a conclusion there's no antenna design that will be the same as the one offered in the guidelines. Even using the same exact values, sizes, pcb thickness, vias, it's not guaranteed that the antenna will perform the same way as on the guidelines. And that's only on simulation, I'm not even talking about real pcb where a ton of additional other factors could appear.

Hey Robert, super nice video!
I just want to give a comment on the biggest radiator in the F antenna or at least the way I like to see it.
I think it is actually the vertical part that connects to ground (what has been called inductor).
That one is effectively a monopole that is vertical to the ground plane (you need to see the groundplane as in the pcb cross section, which is more like a ground knife).
For image theory it will duplicate the size and that is why it is called monopole.
then there is the 90 degree turn and then the line is parallel to the ground.
This still radiates, but less.
You can visualize this using the polarization, as it follows the direction of the current.
The feeding point is at a distance from the ground connection in order to have a matching.
When resonating, the ground has the lower impedance (0) and the open part the highest.
In the middle you find a point that, by adding that capacitance in parallel, you can match it to the desired impedance.
The reason why it radiates most from the vertical line, is because the current is maximum near the ground connection and the voltage is maximum near the open end. This is due to the resonance.
As you might imagine, the radiation come from the oscillating electric current.
These antennas radiates from the magnetic field, unlike a patch antenna that radiates using electric fringing fields.
Keep un the good work and thanks again for the videos!

I absolutely love this format, but please check your audio before recording and touch it up before uploading. Sometimes the speech is very loud and clear, and sometimes it is very quiet and hard to hear.

Although it is possible to use a single antenna for transmission and receiption at the same time, it is rarely used and more common in radar applications. Nevertheless, (at least modern) automotive radars do have different antennas for receiving and transmitting. It is much cheaper than to implement a circulator/directional coupler. Additionally, you get a higher angular resolution using MIMO/beamforming techniques if you have seperate tx/rx antennas. And yes, modern automotive radars have like three transmit and four receive antennas or even more, each with an individual tarnsmitter/receiver and the signals get combined digitally afterwards (see beamforming/MIMO).
Nice video anyways :)

Robert, tôi thích xem các video ngắn hơn, nhưng hầu hết các video của bạn đều có nội dung tuyệt vời mà tôi ước nội dung đó dài 10 giờ

Cool info, is it possible making a PCB trace for GPS ? thanks

That was amazing video! Thanks a lot Robert!!!
Well, it opened my mind, but brought more questions:
If I use a Flex- Rigid PCB where the flex part is the antenna, should I use 30.6mm length for 2.4 Ghz?
How reliable Smith Chart is to tune my antenna? Is there an example how to match the antenna with Smith chart?
So, when I start a design it's really important to know where my product will be pointed out, once the antenna might be facing a metal plate and kill my antenna.

OOooookay! This is very new to me! I am not even interested in this topic and I am not a designer! But simply drawing lines, those lines can be either capacitor or inductor or both. By "simply" I do not mean simply simply, if you know what I mean.
Most of the time capacitance and inductance are determined by huge discrete devices (physical capacitors and wire-wound) or integrated in an insanely small blob by the power of science and technology.

I wish you had a video on using a ceramic omni directional antenna and it effect on antenna design. They are becoming a alternative to a pad copper plus filter set up. I believe phones use them and they are made for bluetooth , etc . They are small package simple design and talk of higher db over range.

Your videos are one of those things that give me knowledge and motivation to hold me on to my current job.
You are impressive 🤯
-Love and thanks from India ❤️

Thank you for making this video and sharing it with all of us.
Can you please explain the issue at 51 minutes 46 seconds, that graph does not show the frequency centered at 2.4 GHz.
In fact it shows the antenna length looks to be a little long and tuned for around 2.3 GHz.
That return loss graph is not centered at 2.4 GHz. Throughout the video, 2.4 GHz was mentioned but the graph does not indicate proper tuning for that frequency. Can you please review and explain?

I'd love to see you interview Alan Wolke (W2AEW). He's got a ton of great RF videos on TH-cam (EG his video #297 on the basics of Smith charts), but you tend to ask good and interesting questions.

this is good shid 👍

Thank you Robert for creating the video, but it's a bit complicated for non-RF engineers.
Would you please make a tutorial on designing the PCB antenna alongside the matching network using Altium designer? it would be much more helpful to understand it.

amazing

w2aew has a nice video on directional couplers with explanation. It's video 196. Should be easy to find.

i prefer LONG videos. more long videos please. thank you.

A magnetic loop is also shorted to ground, but I suppose the inductance saves the day?

Thank you

time: 46:48 minute...
is the Reference Antenna Design can we use RF AND Bluetooth (Combine with 1 Chip) like (ESP-32) IC.. ?
I know many IC Company they recommended us there own Design Antenna..
but in this case if the wifi Frequency are same (2.4Ghz) ..
then can we use other model PCB Antenna ?
is it work same...?

At one hour, 19 minutes, 40, the inverted F PCB antenna is simulated. However there is a difference: On the original drawing from the Cyprus company, the transmission line opens up; wider spacing between ground and the center conductor as it reaches the antenna. That is likely to make the feed balanced, which an inverted F antenna needs. However in the simulation, you narrow to shielding to keep the unbalanced 50 Ohm all the way to the feed point? You do mention the spacing later in the video, but are more concerned about the via placement. Am I missing the obvious here?

There's a lot of good RF info in the YT channel "The Signal Path". VERY recommended.

This is a TI reference design, inverted F...I used it in my products 2 years before.

Any free PCB layout / PCB Antenna simulation tool?

Nice... excellent video..!! thanks Robert and John. (PD: Was anyone hungry..?? 1:08:00 jajaja)

Hi, I am doing a project in which I would do communication between the antennas (PCB),but I am not sure of the module which can send raw data without any encoding
Anyone has any suggestions?

Cool! Realty f cool!

I wonder if the first stage RF amplifier has 50 Ohm input and output impedence, can you connect it to a buffer stage with a high input impedence (so that the buffer stage receives the output of the rf amplifier)?
We can limit to modest frequency of FM radio at 100 mhz. Thanks kindly for the interesting video and for the effort in making it..

Would it be possible for you to get guest speakers to record their audio at their end, so you can merge it with your local audio for better quality? I found it very hard to understand what John was saying as the volume of his voice trailed off towards the end of sentences. This looks like great content, but unfortunately I had to give up on watching this one because I couldn't follow along.

It would had been good if you'd had shown how to make the pcb instructing in altium or easyeda, man I couldn't do my board! that antenas are really hard!

It would have been better to draw the equivalent LC matching circuit of the inverted F antenna while discussing

subsrcribed :)

No! Power does not come OUT of GND, the return current does. Power flows into the feed point.

What about placing a ipex connector in parallel to a pcb antenna, is it that bad at all? Actually it could act like a stub and detune the antena?

Does anyone know a good video of how to match printed IFA antennas with afordable equipment?

Though it connected to ground, I guess the idea it produces such energy burst that the electrons fly of the copper trace into the air
, and as it's 2.4MHz on/off and not DC, there is not many electrons actually making its way all to the end and into the ground.

When i make antennas to and jeah, this is how it goes. :)
No such thing as "short circuit" in antennas

I have used a wire which i added to a existing antenna which i believe is not well designed the signal is limited and why i came here . Adding this wire doubled my range and kept my signal solid as i moved. No bluetooth has a great range most are lucky to have 30 cm line of sight distance and are further limited by walls or door ways which mess with the flow of electrons to the receiver/transmitter. This wire idea works but it requires external mounting not internal mounting which is my preference.

TI support said me that copper thickness does not matter for this antenna due to skin effect.

мне понравилось

There is a lot of good information for beginners here. But I've got to say that the complexity of antenna design is not covered here. Some of the explanations about the simulation and the graphs that it produces are simplistic at best.

I use taoglas antenna

I have a similar series of videos here that walks thru the design, fab and test:
th-cam.com/video/q6f6m2j1nYs/w-d-xo.html

I design antenna for IoT and wireless products daily 😂😂

I need source file for cypress models, please

I like your videos, but it is very annoying when the guest speaks into his microphone such that the audio ranges form barely audible to screaming laud many times per sentence. Please watch for this in future videos.

Cadence/AWR Microwave Office:
Only $990(USD)/month!
Hmm... Do I get that new Tesla or this nifty software instead?
Multitudes, multitudes in the valley of decision: for the day of the LORD is near in the valley of decision.
(Joel 3:14)
Lol. Where's RMS when you need him?

1:27:00 Presenter disparages Cypress' inverted F antenna because it didn't have good results in his software, then admits he's not certain he has the dimensions correct. Meanwhile, if the viewer looks at the image from Cypress and the image that the presenter used as an example, it is easy to see they are not the same. It's no wonder he didn't get good results 🤣

Pity John is always mumbling the 2nd half of sentence, inaudible!