The frequency range for a cellular alarm button in a matchbox - Part 2

A reader of my IoT M2M Cookbook wants to develop a cellular alarm button using NB-IoT and LTE-M. Another buyer of the book has a similar small device. The first part of the article described the relationship between the enclosure and the size of the PCB for the integrated cellular antenna. The recommendation is to find the antenna concept first before filling the small PCB with components.

Finding the lowest frequency for NB-IoT and LTE-M

Check the radio module datasheet to see which frequency bands are supported. There are often close to 30 frequency bands listed. Most wireless IoT devices are designed for specific regions. This means that not all frequency bands need to be supported. These bands overlap in the frequency range. The cellular alarm button should be developed for a country where the European ETSI RED is valid. This specifies which frequency bands are theoretically used for NB-IoT and LTE-M. In the range from about 700 MHz to about 2200 MHz, there are five bands for NB-IoT and LTE-M in Europe. In practice, only three of these bands are primarily used. Operators prefer Band 20 from 791 MHz to 862 MHz and Band 8 from 880 MHz to 960 MHz for NB-IoT and LTE-M. Lower frequencies penetrate walls better than higher frequencies. In urban areas, Deutsche Telekom operates LTE-M individually in Band 3 from 1710 MHz to 1880 MHz. Band 28 from 703 MHz to 803 MHz is not common in Europe, even if the lower frequencies offer better penetration. In Band 20 and Band 8, network operators are already operating LTE antennas on masts. Operators are using the existing sites for NB-IoT and LTE-M. As Deutsche Telekom planned its LTE and GSM in cities in Band 3 at 1800 MHz, these antenna sites were also used for LTE-M. In Band 1 from 1920 to 2170 MHz, NB-IoT and LTE-M are not common.

The lowest frequency for the alarm button in Europe is therefore 791 MHz.

Cellular alarm button worldwide

If the alarm button is to be used worldwide, the USA and Australia have frequency bands starting at around 690 MHz. T-Mobile in the USA uses a band for NB-IoT with the lowest frequency at around 620 megahertz. Even if you exclude T-Mobile in the USA, you need to consider at least 690 MHz as the lowest frequency for antenna design.

690 MHz versus 791 MHz

The percentage difference between the two frequencies is 100% - 690MHz/790MHz = about 13%. The difference in required bandwidth is approximately 960 MHz - 690 MHz = 270 MHz versus 960 MHz - 791 MHz = 169 MHz. The difference in bandwidth required is huge. The problem can be minimised by switching bands and antennas.

Outlook LoRaWAN Europe

In the free study on PCB antennas you can find a LoRa for 868 MHz in Europe and 915 MHz in the USA. The 868 MHz band in Europe has a bandwidth of only 7 MHz. Only part of it is used for LoRaWAN. It is therefore much easier to design an antenna for LoRaWAN than for NB-IoT and LTE-M. The 915 MHz band extends from 902 to 928 MHz. At 26 MHz, it is much larger than the 7 MHz in Europe. But the sensor in the PCB antenna study was supposed to work from 863 to 928 MHz. This is only 65 MHz and significantly less than the 169 MHz for NB-IoT and LTE-M in Europe. The LoRaWAN sensor developer did not achieve this goal. A switchable antenna had to be used to achieve the 65 MHz bandwidth.

The alarm button in a matchbox

If you consult Chu's antenna theorem, you will see that you cannot reduce the size of a dipole antenna arbitrarily. Chu is also quoted in the free study. A monopole antenna in the form of a chip or PCB antenna needs the ground plane of the PCB as a second part of the antenna. This ground plane is part of the antenna and cannot be arbitrarily reduced. The alarm button in the matchbox is therefore not possible with NB-IoT and LTE-M.

Flute length and frequency range

The length of the flute determines the lowest frequency of the flute. The same applies to the length of the ground plane for the antenna.

Conclusion

Not only the lowest frequency is important, but also the necessary frequency bandwidth. It may not be possible on a small PCB to reach the lowest frequency. If you achieve the lowest frequency, you may not achieve the necessary frequency bandwidth. Therefore, start with a test setup of the antenna design as described above. If you don't do this, you will end up with an expensive redesign of the PCB, as described in the study for the LoRaWAN sensor.

Sources:

Extract from the IoT M2M Cookbook: https://www.gsm-modem.de/M2M/m2m_iot_cookbook/

Free PCB antenna study: https://www.akoriot.com/white-papers/

MegiQ VNA: https://www.akoriot.com/megiq-vna-0440/

Global LTE bands and frequencies: https://en.wikipedia.org/wiki/LTE_frequency_bands

Remote training on the MegiQ VNA: On request to harald.naumann (at) lte-modem.com

Imprint

• Harald Naumann, Ludwig-Kaufholz-Weg 4, 31535 Neustadt, Germany
• Contact: harald.naumann (at) lte-modem.com, Phone: +49-5032 801 9985, Mobile:+49-152-33877687