Calculating field strength mV/m at distance d - check me

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Discussion Overview

The discussion revolves around calculating electric field strength in millivolts per meter (mV/m) at various distances from a source, specifically focusing on both electrostatic fields from point charges and electromagnetic fields from radio signals. Participants explore the implications of distance on field strength and the differences between near-field and far-field conditions.

Discussion Character

  • Technical explanation
  • Debate/contested
  • Mathematical reasoning

Main Points Raised

  • Some participants assert that electric field strength is inversely proportional to the square of the distance for point charges, while others clarify that this relationship holds under specific conditions.
  • One participant notes that for radio signals from an omni-directional antenna, the field strength varies as 1/r in the far field, contrasting with the 1/r² relationship for electrostatic fields.
  • A formula for calculating electric field strength from a grounded monopole antenna is presented, emphasizing the importance of accounting for ground losses at higher frequencies.
  • Participants discuss specific calculations for electric field strength at distances of 2 km and 4 km, with one participant initially miscalculating the result for 4 km before correcting it.
  • Another participant provides a link to a field strength calculator, suggesting it may be useful for further exploration.

Areas of Agreement / Disagreement

There is no consensus on the applicability of the inverse square law for electric field strength in this context, as participants present differing views on the nature of the fields being discussed and the appropriate formulas to use.

Contextual Notes

Participants highlight the need to consider factors such as the type of source (point charge vs. antenna) and the distance from the source when applying formulas for electric field strength. The discussion also touches on the distinction between near-field and far-field effects.

Fran3
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it's been awhile for me so check if I'm remembering this right... Thanks.

electric field strength is inversely proportional to distance squared... right?

So if the electric field strength is 1,000 mV/m at 1 meter then the following is true... right?

km______mV/m________ the math
1________1000 .00______=reference point
2_________250.00_______ =1000/(2^2)
3_________111.11________=1000/(3^2)
4__________62.50________=1000/(4^2)
5__________40.00________etc

thanks for any help.
 
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Fran3 said:
electric field strength is inversely proportional to distance squared

...from a point charge. If the source of the field is a point charge, or at least small enough compared to the distances involved, that a point is a good approximation, then your calculations are correct.
 
Fran3 said:
electric field strength is inversely proportional to distance squared... right?

This depends on your setup. It is true for a point charge or a spherically symmetric charge distribution.
 
In this case we are talking about field strength of a radio signal being radiated from an omni-directional antenna.

In the example the radio signal measures 1,000 mV/m at a distance of 1km and we want to calculate the field strength at different distances.

Ignoring any mitigating factors such as attenuation through structures or whatever... are our calculations correct for what we could consider near-field distances and also characterize as "ground wave" distinguishing from "sky wave" or "skip".

thanks for the help.
 
Fran3 said:
field strength of a radio signal being radiated from an omni-directional antenna.

This is different from the electrostatic field of a point charge. In this case, in the far field the amplitude of the electromagnetic wave varies as 1/r, not 1/r2. It's the radiated power density (W/m2) that varies as 1/r2.
 
jtbell said:
This is different from the electrostatic field of a point charge. In this case, in the far field the amplitude of the electromagnetic wave varies as 1/r, not 1/r2. It's the radiated power density (W/m2) that varies as 1/r2.
A convenient formula for the electric field strength from a grounded monopole antenna in mV/m is (300 sqrt P) / D, where D is distance in km and P is power in kW. It is necessary to be very careful about ground losses, especially where the frequency exceeds about 1 MHz.
 
So if
P=4kW
D=2km
electric field strength = ([300*sqrt(4)]/2) = 600/2 = 300 mV/m

and for D=4km
electric field strength = ([300*sqrt(4)]/4) = 600/4 = 300 mV/m

correct?

and thanks !
 
Fran3 said:
600/4 = 300 mV/m

Check your arithmetic. :oldwink:
 
  • #10
Woops! When you cut and paste you should complete all the edits in the pasted text. Yep, should have read...

So if
P=4kW
D=2km
electric field strength = ([300*sqrt(4)]/2) = 600/2 = 300 mV/m

and for D=4km
electric field strength = ([300*sqrt(4)]/4) = 600/4 = 150 mV/m

And Dave, thanks for the link. Very handy.
 

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