meshtastic/docs/hardware/antenna/non-aerial.mdx

---
id: non-aerial
title: Non-aerial factors affecting transmission
sidebar_label: Non-aerial factors
slug: /hardware/non-aerial
---

Unless you're using your devices in a vacuum, with clear line of sight between aerials the following will have an effect:

- Weather (temperature, humidity, and air pressure),
- Transmission power, bandwidth, spreading factor, and other associated channel factors,
- Number of nodes within reach of the mesh (affects retries consequent duty cycle hit),
- Absorption by materials (with varying degrees attenuation, by material and depth),
- Reflection off surfaces (and channeling through material tunnels, including warm / cold air tunnels commonly present in the atmosphere),
- Diffraction around obstacles (over forests and around corners).
- [Fresnel Zone](They may not have been selected for your given frequency range, tuned or of a quality design.) - Football shape between antennas that must be clear of obstructions or else the signal is attenuated.

### Environmental factors

For a bit of light reading on environmental research:

- [RF attenuation in vegetation](https://web.archive.org/web/20201216041455/https://www.itu.int/dms_pubrec/itu-r/rec/p/R-REC-P.833-9-201609-I!!PDF-E.pdf) (yes really); if you wander through the woods wondering how your RF is bouncing off leaves dependent on their variety, and wind speed … well you do, now.
- [RF attenuation with various building materials](https://www.ofcom.org.uk/__data/assets/pdf_file/0016/84022/building_materials_and_propagation.pdf).
- This one by ITU again is very detailed in its [analysis of the drivers of attenuation](https://web.archive.org/web/20211005174833/https://www.itu.int/dms_pubrec/itu-r/rec/p/R-REC-P.2040-1-201507-I!!PDF-E.pdf) (I wasn’t aware that all EMF radiation exhibits reflection / transmission characteristics akin to light hitting a material boundary. So, depending on the angle of incidence, material and the EMF wavelength, it will be reflected and / or transmitted through).
- These RF bands are also made more [noisy by adjacent LTE](https://www.ofcom.org.uk/__data/assets/pdf_file/0023/55922/lte-coexistence.pdf)

In summary - wavelengths in Europe fair well in plain sight, curve over not-so-tall obstacles (including trees), and they reflect off surfaces at low angles of incidence. They go through humans without much attenuation; but not brick, stone, or anything with more attenuation than glass / Kevlar. Oh, and don’t sit under an LTE tower and expect it to be plain sailing. RF emissions at adjacent frequencies can interfere at a high enough power.
-												Antennas

											
										
										
											2021-05-09 06:51:23 -07:00
+								---
 								id: non-aerial
 								title: Non-aerial factors affecting transmission
 								sidebar_label: Non-aerial factors
 								slug: /hardware/non-aerial
 								---
-												Many documentation typos fixed

											
										
										
											2022-01-02 22:53:45 -08:00
+								Unless you're using your devices in a vacuum, with clear line of sight between aerials the following will have an effect:
-												Format with prettier

											
										
										
											2022-03-08 23:51:46 -08:00
-												Many documentation typos fixed

											
										
										
											2022-01-02 22:53:45 -08:00
+								- Weather (temperature, humidity, and air pressure),
 								- Transmission power, bandwidth, spreading factor, and other associated channel factors,
 								- Number of nodes within reach of the mesh (affects retries consequent duty cycle hit),
-												Antennas

											
										
										
											2021-05-09 06:51:23 -07:00
+								- Absorption by materials (with varying degrees attenuation, by material and depth),
-												Many documentation typos fixed

											
										
										
											2022-01-02 22:53:45 -08:00
+								- Reflection off surfaces (and channeling through material tunnels, including warm / cold air tunnels commonly present in the atmosphere),
-												Antennas

											
										
										
											2021-05-09 06:51:23 -07:00
+								- Diffraction around obstacles (over forests and around corners).
-												Many documentation typos fixed

											
										
										
											2022-01-02 22:53:45 -08:00
+								- [Fresnel Zone](They may not have been selected for your given frequency range, tuned or of a quality design.) - Football shape between antennas that must be clear of obstructions or else the signal is attenuated.
-												Antennas

											
										
										
											2021-05-09 06:51:23 -07:00
-												Small fixes

											
										
										
											2021-05-09 07:03:35 -07:00
+								### Environmental factors
-												Antennas

											
										
										
											2021-05-09 06:51:23 -07:00
 								For a bit of light reading on environmental research:
-												Format with prettier

											
										
										
											2022-03-08 23:51:46 -08:00
-												Fixed links.

The original files appear to be gone/moved, so changed to recent
Internet Archive Wayback links instead.

											
										
										
											2022-01-03 20:06:57 -08:00
+								- [RF attenuation in vegetation](https://web.archive.org/web/20201216041455/https://www.itu.int/dms_pubrec/itu-r/rec/p/R-REC-P.833-9-201609-I!!PDF-E.pdf) (yes really); if you wander through the woods wondering how your RF is bouncing off leaves dependent on their variety, and wind speed … well you do, now.
-												Typos, spelling, and grammar corrected (#3)

Thanks to aspell and languagetool. Hand picked from these, there are too
many strange things in the English language to be perfectly syntactical.
											
										
										
											2021-12-27 11:39:42 -08:00
+								- [RF attenuation with various building materials](https://www.ofcom.org.uk/__data/assets/pdf_file/0016/84022/building_materials_and_propagation.pdf).
-												Fixed links.

The original files appear to be gone/moved, so changed to recent
Internet Archive Wayback links instead.

											
										
										
											2022-01-03 20:06:57 -08:00
+								- This one by ITU again is very detailed in its [analysis of the drivers of attenuation](https://web.archive.org/web/20211005174833/https://www.itu.int/dms_pubrec/itu-r/rec/p/R-REC-P.2040-1-201507-I!!PDF-E.pdf) (I wasn’t aware that all EMF radiation exhibits reflection / transmission characteristics akin to light hitting a material boundary. So, depending on the angle of incidence, material and the EMF wavelength, it will be reflected and / or transmitted through).
-												Antennas

											
										
										
											2021-05-09 06:51:23 -07:00
+								- These RF bands are also made more [noisy by adjacent LTE](https://www.ofcom.org.uk/__data/assets/pdf_file/0023/55922/lte-coexistence.pdf)
-												Many documentation typos fixed

											
										
										
											2022-01-02 22:53:45 -08:00
+								In summary - wavelengths in Europe fair well in plain sight, curve over not-so-tall obstacles (including trees), and they reflect off surfaces at low angles of incidence. They go through humans without much attenuation; but not brick, stone, or anything with more attenuation than glass / Kevlar. Oh, and don’t sit under an LTE tower and expect it to be plain sailing. RF emissions at adjacent frequencies can interfere at a high enough power.