Effective Path Length using Reduction Factor Solution

STEP 0: Pre-Calculation Summary
Formula Used
Effective Path Length = Slant Length*Reduction Factor
Leff = Lslant*rp
This formula uses 3 Variables
Variables Used
Effective Path Length - (Measured in Meter) - Effective Path Length refers to the total distance that a radio signal travels between a transmitter and a receiver, taking into account the effects of multipath propagation.
Slant Length - (Measured in Meter) - Slant Length refers to the length of path followed by the radio wave signal as it travels from the transmitting satellite to the receiving satellite ground station.
Reduction Factor - The reduction factor represents the factor by which the effective path length is reduced compared to the straight-line distance between the observer and the satellite.
STEP 1: Convert Input(s) to Base Unit
Slant Length: 14.117 Kilometer --> 14117 Meter (Check conversion here)
Reduction Factor: 0.85 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Leff = Lslant*rp --> 14117*0.85
Evaluating ... ...
Leff = 11999.45
STEP 3: Convert Result to Output's Unit
11999.45 Meter -->11.99945 Kilometer (Check conversion here)
FINAL ANSWER
11.99945 Kilometer <-- Effective Path Length
(Calculation completed in 00.004 seconds)

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14 Radio Wave Propagation Calculators

Rain Attenuation in Decibels
Go Rain Attenuation = Specific Attenuation*Rain Rate^Specific Attenuation Coefficient*Slant Length*Reduction Factor
Specific Attenuation in Clouds or Fogs
Go Specific Attenuation due to Clouds = (Total Content of Liquid Water*Specific Attenuation Coefficient)/sin(Angle of Elevation)
Regression of Nodes
Go Regression Node = (Mean Motion*SCOM Constant)/(Semi Major Axis^2*(1-Eccentricity^2)^2)
Earth Station Altitude
Go Earth Station Altitude = Height of Rain-Slant Length*sin(Angle of Elevation)
Rain Height
Go Height of Rain = Slant Length*sin(Angle of Elevation)+Earth Station Altitude
Distribution of Rain Attenuation
Go Distribution of Rain Attenuation = 1+((2*Horizontal Projection Length)/(pi*Diameter of Rain Cell))
Horizontal Projection of Slant Length
Go Horizontal Projection Length = Slant Length*cos(Angle of Elevation)
Effective Path Length
Go Effective Path Length = Total Attenuation/Specific Attenuation
Total Attenuation
Go Total Attenuation = Effective Path Length*Specific Attenuation
Specific Attenuation
Go Specific Attenuation = Total Attenuation/Effective Path Length
Reduction Factor using Slant Length
Go Reduction Factor = Effective Path Length/Slant Length
Slant Length
Go Slant Length = Effective Path Length/Reduction Factor
Effective Path Length using Reduction Factor
Go Effective Path Length = Slant Length*Reduction Factor
Plasma Frequency Terms of Electronic Density
Go Plasma Frequency = 9*sqrt(Electron Density)

Effective Path Length using Reduction Factor Formula

Effective Path Length = Slant Length*Reduction Factor
Leff = Lslant*rp

What is Rain Attenuation?

The depletion of electromagnetic energy during propagation through rain, caused by raindrop scattering and absorption.

How to Calculate Effective Path Length using Reduction Factor?

Effective Path Length using Reduction Factor calculator uses Effective Path Length = Slant Length*Reduction Factor to calculate the Effective Path Length, The Effective Path Length using Reduction Factor formula is defined as simply the distance between two nodes, measured as the number of edges between them. Effective Path Length is denoted by Leff symbol.

How to calculate Effective Path Length using Reduction Factor using this online calculator? To use this online calculator for Effective Path Length using Reduction Factor, enter Slant Length (Lslant) & Reduction Factor (rp) and hit the calculate button. Here is how the Effective Path Length using Reduction Factor calculation can be explained with given input values -> 0.034 = 14117*0.85.

FAQ

What is Effective Path Length using Reduction Factor?
The Effective Path Length using Reduction Factor formula is defined as simply the distance between two nodes, measured as the number of edges between them and is represented as Leff = Lslant*rp or Effective Path Length = Slant Length*Reduction Factor. Slant Length refers to the length of path followed by the radio wave signal as it travels from the transmitting satellite to the receiving satellite ground station & The reduction factor represents the factor by which the effective path length is reduced compared to the straight-line distance between the observer and the satellite.
How to calculate Effective Path Length using Reduction Factor?
The Effective Path Length using Reduction Factor formula is defined as simply the distance between two nodes, measured as the number of edges between them is calculated using Effective Path Length = Slant Length*Reduction Factor. To calculate Effective Path Length using Reduction Factor, you need Slant Length (Lslant) & Reduction Factor (rp). With our tool, you need to enter the respective value for Slant Length & Reduction Factor and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Effective Path Length?
In this formula, Effective Path Length uses Slant Length & Reduction Factor. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Effective Path Length = Total Attenuation/Specific Attenuation
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