How do NFC antennas work? We will discuss that in a simple manner and try to explain why NFC antennas aren’t really antennas at all (like the dipole antenna or the Horn Antenna). But first, let’s give some background on NFC.
NFC stands for Near Field Communications and goes by the acronym NFC. NFC is simply a set of standards for smartphones or whatever to establish communication with each other by bringing them into close together (typically 0-5 centimeters). This set of standards is just like 802.11b or 802.11n for WIFI – it sets the protocols to send and receive information. The application of NFC include swiped proximity payments (such as Google wallet for paying at Starbucks), information exchange at small distances (for instance, touching smartphones to share contact information), and simplified setup of devices such as Wi-Fi or Bluetooth. Communication is also possible between an NFC device and an unpowered NFC chip, called a tag (as in RFID tag).
So NFC is just a method of communication between two devices at short distance. What makes the NFC antenna design simple or easy? If you know much about antennas, the first question you might ask is what the operating frequency of NFC is. It turns out that these devices operate around 13.56 MHz. The corresponding wavelength is 22 meters long – this means to get a nice half-wave dipole antenna (that radiates well) we would need a device about 11 meters in length.
Now, clearly we have NFC antennas on smartphones or there would be no Google Wallet, for instance. So the challenge in NFC antenna design is to obtain a “radiating” structure when the NFC antenna area may be limited to 3″x1″ (or 7 cm * 2.5 cm). Hence, we are talking about fitting an antenna into a volume where the maximum linear dimension is about 0.5% or less of a wavelength. And from antenna theory, we know that you won’t get any radiation out of such a small device.
To sum up the discussion so far: NFC antennas operate at low frequency (large wavelengths) on small devices. A consequence of this is that the radiation efficiency of an NFC antenna will be about 0. So how then do they work?
You may recall from your electric circuits classes that inductors can be made to couple together – that is, there exists mutual coupling. If the magnetic fields from one inductor pass near another inductor, an induced current will exist within the second inductor. This is contactless energy transfer – exactly what NFC requires.
Hence, an NFC antenna isn’t an antenna at all – it is really just a big inductor. In general, the larger the inductance of the antenna can be made, the better it will perform. Note that this doesn’t mean you can place a very small chip inductor as your NFC antenna – the magnetic fields on these inductors are tightly wound and don’t extend much beyond the chips themselves. Rather, a good NFC antenna is as large of a wrapped coil of wire as possible. Recall that a loop of wire around a material gives a strong magnetic field within the loop (and generally the more turns you have the more inductance you create). Hence, NFC antennas are often simply loops of wire, occupying as much surface area as the device allows.
One final note related to NFC antenna design. We’ve already stated that the larger the surface area, the better performing your NFC antenna will be. We haven’t mentioned anything about volume. Can the NFC antenna be infinitely thin? The answer is yes – if there is no metal or conductive material around the NFC antenna. If you know much about electromagnetics, you will know that a ground plane directly beneath magnetic or electric fields will very much degrade them. Hence, performance degrades for the NFC inductor style antenna when placed near a metallic surface. As a result, for performance the height of the NFC loop will need maximized. If the space is near zero, the performance will suffer.
One small trick to get around this is to use high permeability sheets (ferrite, iron based, whatever) between the NFC antenna and the metallic ground plane. This serves to concentrate the magnetic fields, effectively making them think the distance is larger between the NFC antenna and the ground plane. This helps to alleviate the height problem, but does not eliminate it.
This concludes our discussion of NFC antennas and some of the basics in NFC antenna design. As you can see, this is a very atypical antenna, and really I don’t classify it as an antenna at all.
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