Single vegetative obstruction model

The ITU Single Vegetative Obstruction Model is a Radio propagation model that quantitatively approximates the attenuation due to the vegetation in the middle of a telecommunication link.

The model is applicable to scenarios where no end of the link is completely inside foliage, but a single plant or tree stands in the middle of the link.

Frequency = Below 3 GHz and Over 5 GHz Depth = Not specified

The single vegetative obstruction model is formally expressed as,

${\displaystyle A={\begin{cases}d\gamma {\mbox{ , frequency}}<3GHz\\R_{f}d\;+\;k[1-e^{(R_{f}-R_{i}){\frac {d}{k}}}]{\mbox{ , frequency}}>5GHz\end{cases}}}$

where, A = The Attenuation due to vegetation. Unit: Decibel(dB).

d = Depth of foliage. Unit: Meter (m).

${\displaystyle \gamma }$ = Specific attenuation for short vegetative paths. Unit: Decibel / Meter (dB/m).

R_i = The initial slope of the attenuation curve.

R_f = The final slope of the attenuation curve.

f = The frequency of operations.Unit: Giga Hertz (GHz).

k = Empirical constant.

Initial slope is calculated as:

${\displaystyle R_{i}\;=\;af}$

And the final slope as:

${\displaystyle R_{f}\;=\;bf^{c}}$

where,

a, b and c are empirical constants (given in the table below).

k is computed as:

${\displaystyle k=k_{0}\;-\;10\;\log {[A_{0}\;(1\;-\;e^{\frac {-A^{i}}{A_{0}}})(1-e^{R_{f}f})]}}$

where,

k₀ = Empirical constant (given in the table below).

R_f = Empirical constant for fequency dependent attenuation.

A₀ = Empirical attenuation constant (given in the table below).

A_i = Illumination area.

A_i is calculated in using any of the equations below. A point to note is that, the terms h, h_T, h_R, w, w_T and w_R are defined perpendicular to the (assumed horizontal) line joining the transmitter and receiver. The first three terms are measured vertically and the other thee are measured horizontally.

Equation 1: ${\displaystyle A_{i}\;=\;min(w_{T},w_{R},w)\;x\;min(h_{T},h_{R},h)}$

Equation 2: ${\displaystyle A_{i}\;=\;min(2d_{T}\;\tan {\frac {a_{T}}{2}}.2d_{R}\tan {\frac {a_{R}}{2}},w)\;x\;min(2d_{T}\tan {\frac {e_{T}}{2}}.2d_{R}\tan {\frac {e_{R}}{2}},h)}$

where,

w_T = Width of illuminated area as seen from the transmitter. Unit: Meter (m)

w_R = Width of illuminated area as seen from the receiver. Unit: Meter (m)

w = Width of the vegetation. Unit: Meter (m)

h_T =Height of illuminated area as seen from the transmitter. Unit: Meter (m)

h_R = Height of illuminated area as seen from the receiver. Unit: Meter (m)

h = Height of the vegetation. Unit: Meter (m)

a_T = Azimuth beamwidth of the transmitter. Unit: Degree or Radian

a_R = Azimuth beamwidth of the receiver. Unit: Degree or Radian

e_T = Elevation beamwidth of the transmitter. Unit: Degree or Radian

e_R = Elevation beamwidth of the receiver. Unit: Degree or Radian

d_T = Distance of the vegetation from transmitter. Unit: Meter(m)

d_R = Distance of the vegetation from receiver. Unit: Meter(m)

Empirical constants a, b, c, k₀, R_f and A₀ are used as tabulated below.

The model predicts the explicit path loss due to the existence of vegetation along the link. The total path loss includes other factors like free space loss which is not included in this model.

Over 5GHz, the equations suddenly become extremely complex in consideration of the equations for below 3 GHz. Also, this model does not work for frequency between 3 GHz and 5 GHz.

• Introduction to RF propagation, John S. Seybold, 2005, Wiley.

• Radio propagation model
• Weissberger's Model
• Early ITU Model