Log-distance path loss model: Information from Answers.com

The log-distance path loss model is a radio propagation model that predicts the path loss a signal encounters inside a building or densely populated areas over distance.

1 Applicable to / Under conditions
2 Mathematical formulation
- 2.1 The model
- 2.2 Corresponding non-logarithmic model
3 Empirical coefficient values for indoor propagation
4 References
5 Further reading
6 See also

Applicable to / Under conditions

The model is applicable to indoor propagation modeling.

Mathematical formulation

The model

Log-distance path loss model is formally expressed as:

$PL\;=P_{Tx_{dBm}}-P_{Rx_{dBm}}\;=\;PL_0\;+\;10\gamma\;\log_{10} \frac{d}{d_0}\;+\;X_g,$

where

P L

is the total path loss measured in Decibel (dB)

$P_{Tx_{dBm}}\;=10\log_{10} \frac{P_{Tx}}{1mW}$ is the transmitted power in dBm, where

P T x

is the transmitted power in watt.

$P_{Rx_{dBm}}\;=10\log_{10} \frac{P_{Rx}}{1mW}$ is the received power in dBm, where

P R x

is the received power in watt.

P L 0

is the path loss at the reference distance d₀. Unit: Decibel (dB)

d

is the length of the path.

d 0

is the reference distance, usually 1 km (or 1 mile).

γ

is the path loss exponent.

X g

is a "normal( or Gaussian)" random variable with zero mean, reflecting the attenuation (in decibel) caused by flat fading. In case of no fading, this variable is 0. In case of only shadow fading or slow fading, this random variable may have Gaussian distribution with $\sigma\;$ standard deviation in dB, resulting in log-normal distribution of the received power in Watt. In case of only fast fading caused by multipath propagation, the corresponding gain in times $F_g\;=-10\log_{10}X_g$ may be modelled as a random variable with Rayleigh distribution or Ricean distribution.

Corresponding non-logarithmic model

This corresponds to the following non-logarithmic gain model:

$\frac{P_{Rx}}{P_{Tx}}\;=\;\frac{c_0F_g}{d^{\gamma}}$

where

$c_0\;=\;{d_0^{\gamma}}10^{\frac{-L_0}{10}}$ is the average multiplicative gain at the reference distance $d 0$ from the transmitter. This gain depends on factors such as carrier frequency, antenna heights and antenna gain, for example due to directional antennas; and

$F_g\;=\;10^{\frac{-X_g}{10}}$ is a stochastic process that reflects flat fading. In case of only slow fading (shadowing), in may have log-normal distribution with parameter $\sigma\;$ dB. In case of only fast fading due to multipath propagation, its amplitude may have Rayleigh distribution or Ricean distribution.

Empirical coefficient values for indoor propagation

Empirical measurements of coefficients $γ$ and $σ$ in dB have shown the following values for a number of indoor wave propagation cases. ^[1]

Building Type	Frequency of Transmission	$γ$	$σ$ [dB]
Vacuum, infinite space		2.0	0
Retail store	914 MHz	2.2	8.7
Grocery store	914 MHz	1.8	5.2
Office with hard partition	1.5 GHz	3.0	7
Office with soft partition	900 MHz	2.4	9.6
Office with soft partition	1.9 GHz	2.6	14.1
Textile or chemical	1.3 GHz	2.0	3.0
Textile or chemical	4 GHz	2.1	7.0, 9.7
Metalworking	1.3 GHz	1.6	5.8
Metalworking	1.3 GHz	3.3	6.8

References

^ Wireless communications principles and practices, T. S. Rappaport, 2002, Prentice-Hall

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Log-distance path loss model

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