"Antenna matching networks for dummies"?

I'm working on a project where I'm building a custom NFC antenna that will be connected to a PN532 NFC controller. The antenna has already been designed (for 13.56 MHz) and built, the PN532 is also here, what's missing is the matching network between transceiver and antenna.

Problem now is, the ham operator that built the antenna for me can't continue with the project and I'm left with an antenna but no matching network. I don't have access to a network analyzer, and only quite basic knowledge about RF and antennas. However, I do have sufficient electronics knowledge to build a given circuit, and I know how to operate an oscilloscope and a signal generator.

The question now is: with these tools at hand, can I somehow fudge together a working matching network? Or should I rather find another ham operator? ;-)

Best, Florian

• Do you know the complex impedance of the antenna? Oct 30, 2017 at 9:52
• @AndrejaKo - unfortunately not, I think measuring this is exactly what the answer below describes, correct? Oct 30, 2017 at 10:10
• Correct! However, just like 287001 said, it's not very easy to do the measurements with just the scope and any cable you use between the measurement point and the antenna is going to be an impedance transformer and will affect the measurement. Depending on your budget, you might want to get an antenna analyzer. They're common in amateur radio shops and better ones will tell you the complex impedance. You might get an OK one for ~300€, for 500€ you can get a small PC-based VNA. Oct 30, 2017 at 11:27
• None of those words in the title belong together! D: Oct 30, 2017 at 17:52

The frequency is low enough for measurements with oscilloscope. Add a small few ohms resistor in series with your antenna. Be sure that the resistor is not a coil. It must be resistive at the operating frequency.

Feed with a signal generator a sinewave into the antenna at the right operating frequency. Measure at the same time the voltage and the current and their phase difference. You can calculate the impedance of the antenna as a complex phasor. A single frequency LC matching network for transforming the measured complex impedance to a wanted resistance is a popular training problem in phasor calculus books.

You can also tune the system when measuring the antenna through a matching network. There are plenty of variable tuning networks available in sourcebooks. The tuning is quite a job without knowing anything beforehand. The goal = no phase shift between the current and voltage, the resistance = the specified one.

WARNINGS:

• all reflective parts near the antenna change its behaviour radically. The final placement would be optimal. When doing the measurements you can test how sensitive your system actually is.
• the cable between the antenna and the matching network should be as short as possible to avoid long reflections in the cable.
• the cable is a part of the reactive system, so it cannot be changed between the measuring point and the antenna, the calculated matching network is right only for just the point where the measurements were done.

ADD: This is not beginner's job. One must understand and be able to perform complex impedance calculations, if he wants to calculate the network. Also the no-nonsense measurements with oscilloscope and signal generator even at so low as 13,56MHz are far from trivial. Get an experienced local partner. By trial and error you will get to nothing except burn your transmitter because a bad mismatch can cause a serious overvoltage to output.

ADD2: If you happen to understand well the math (=impedance as phasor) behind matching but feel yourself too unsure to perform the calculations reliably, you can use a circuit simulator to find the right component values for the network after good enough guessing. Reliably measured complex impedance is a must for this as the starting point.