|
Converting From mV/m To Decayed mW (ERP)
I've seen the different conversions for mW, mV, mV/m, dBm, mostly based
on 50 ohms. What I'm interested in is converting a given field strength mV/m, at a given distance for a particular frequency, to the equivalent (decayed) baseline wattage. For instance, in section 73.318, the FCC defines the FM blanket overload boundary as 562 mV/m (115 dBu), having a distance equalling ..394 * KW^.5 (ERP), where (I believe) ".394" is supposed to be 50000^.5/562. So, assuming flat terrain with "raw reception" (meaning no antenna and line gain/loss), what would the equivalent ERP wattage be (i.e., if you took a field strength meter and held it next to a transmitter, what would the wattage be to produce 562 mV/m?)? Since wattge can be found from mV/m, what would the equation for decayed wattage (mW_d) be, given an ERP (KW_erp), frequency (MHz) and distance (Km)? Instead of 50, should 2*Pi*60 Hz (~=~ 377) be used for ohms? ~Kaimbridge~ ----- Wikipedia-Contributor Home Page: http://en.wikipedia.org/wiki/User:Kaimbridge ***** Void Where Permitted; Limit 0 Per Customer. ***** |
Converting From mV/m To Decayed mW (ERP)
On 24 ene, 02:29, "Kaimbridge" wrote: I've seen the different conversions for mW, mV, mV/m, dBm, mostly based on 50 ohms. What I'm interested in is converting a given field strength mV/m, at a given distance for a particular frequency, to the equivalent (decayed) baseline wattage. For instance, in section 73.318, the FCC defines the FM blanket overload boundary as 562 mV/m (115 dBu), having a distance equalling .394 * KW^.5 (ERP), where (I believe) ".394" is supposed to be 50000^.5/562. So, assuming flat terrain with "raw reception" (meaning no antenna and line gain/loss), what would the equivalent ERP wattage be (i.e., if you took a field strength meter and held it next to a transmitter, what would the wattage be to produce 562 mV/m?)? Since wattge can be found from mV/m, what would the equation for decayed wattage (mW_d) be, given an ERP (KW_erp), frequency (MHz) and distance (Km)? Instead of 50, should 2*Pi*60 Hz (~=~ 377) be used for ohms? ~Kaimbridge~ ----- Wikipedia-Contributor Home Page: http://en.wikipedia.org/wiki/User:Kaimbridge ***** Void Where Permitted; Limit 0 Per Customer. ***** Hello, The formula you should use (or propagation graph) to calculate the ERP (or input wattage), based on field strength measurement, depends on many factors like: Frequency, height of transmitter and receiver, ground properties, antenna gain, etc. The reason for that is that at certain distance from the transmitting antenna, the ground reflected wave interferes with the direct wave. Whether the reflected wave will result in destructive or constructive interference depends on the path length difference and ground reflection coefficient. At large difference, there is always destructive interference (this causes that in reality for VHF and low UHF, field strength is inversely proportional to distance squared). Maybe you can give some more details about antenna type, transmitter height, distance, frequency, etc. One formula to calculate the path loss that incorporates ground reflection is the "two-ray propagation formula". It comes in two versions one without sinusoidal functions (the simple one) and the complete one (with goniometric functions) that also gives reasonable results when the antenna is more close to the antenna. At large distance other phenomena become dominant (for example over the horizon diffraction). Hope this will help you, Wim PA3DJS |
Converting From mV/m To Decayed mW (ERP)
One of the broadcast engineeer groups would be better suited for your
problem... This is a calculation that is not relevant to hams.. denny / k8do On Jan 23, 8:29 pm, "Kaimbridge" wrote: I've seen the different conversions for mW, mV, mV/m, dBm, mostly based on 50 ohms. What I'm interested in is converting a given field strength mV/m, at a given distance for a particular frequency, to the equivalent (decayed) baseline wattage. For instance, in section 73.318, the FCC defines the FM blanket overload boundary as 562 mV/m (115 dBu), having a distance equalling .394 * KW^.5 (ERP), where (I believe) ".394" is supposed to be 50000^.5/562. So, assuming flat terrain with "raw reception" (meaning no antenna and line gain/loss), what would the equivalent ERP wattage be (i.e., if you took a field strength meter and held it next to a transmitter, what would the wattage be to produce 562 mV/m?)? Since wattge can be found from mV/m, what would the equation for decayed wattage (mW_d) be, given an ERP (KW_erp), frequency (MHz) and distance (Km)? Instead of 50, should 2*Pi*60 Hz (~=~ 377) be used for ohms? ~Kaimbridge~ ----- Wikipedia-Contributor Home Page: http://en.wikipedia.org/wiki/User:Kaimbridge ***** Void Where Permitted; Limit 0 Per Customer. ***** |
Converting From mV/m To Decayed mW (ERP)
"Kaimbridge" wrote:
I've seen the different conversions for mW, mV, mV/m, dBm, mostly based on 50 ohms. What I'm interested in is converting a given field strength mV/m, at a given distance for a particular frequency, to the equivalent (decayed) baseline wattage. _________________ The radiated power needed to generate a given, free-space field strength of course depends on the length of the propagation path to that value of field strength. Re-arranging the FCC equation to solve for the radiated power needed to generate 562 mV/m when distance in kilometers is known gives P = D^2/0.1552 So if there is a need to limit the field strength to 562 mV/m at a location 1 km from the antenna, we see that ERP cannot exceed ~6.44 kW. Another way of doing it is to massage this "classic" equation. Field Strength in dB above 1 microvolt/meter = 104.77 + ERPi - 20 log (D) where ERPi = Effective Radiated Power in dB referenced to 1kW from an isotropic radiator D = Distance in kilometers It gives the same answer as the simpler equation above. I think this will answer your question, if I understood it right. RF |
Converting From mV/m To Decayed mW (ERP)
On Jan 24, 2:45 pm, "mpm" wrote:
On Jan 23, 8:29?pm, "Kaimbridge" wrote: What I'm interested in is converting a given field strength mV/m, at a given distance for a particular frequency, to the equivalent (decayed) baseline wattage. If I understand what you're asking, your question really centers around how to calculate Free Space Loss. The Friis Equation will allow you to do this, and it is a relatively simple matter to derive Free Space Path Loss in decibel form from the Friis Equation. I'm not su Is this the same (or at least related to) W/m^2? The problem I see with these is that, as distance approaches 0, KW approahes oo and what I'm looking for shouldn't be greater than the transmitter's erp. What got me on this idea, is a few weeks go I was visiting up in the NH White Mountains and was checking out the AM/FM bands (I'm a radio geek! P=). When I got home, I went to the FCC site to create a bandscan of the area. The designation used was the radius from a point. I quickly realized that this was less than ideal, as--using 100 km radius, as an example--100 W stations at that distance would be listed along with 50 and 100 KW! What would be much more useful would be a listing of stations that provide--st least the theoretical baseline value (i.e., not considering intervening local terrain or one's receiver sensitivity and antenna gain)--a given mV/m or mW at that point (thus listing 100 W stations out to 15 km, whereas 50 KW stations out to 75 km and 100 KW to 130 km would be listed). Think of it this way: If you turned on a 100 W lightbulb in the middle of a field at night and held a book page right up to it, you would be able to read it clearly; if you moved about 10 feet away (with the book page still facing the lightblb, unobstructed), you would have difficulty trying to read it, as only about the equivalent of (e.g.) 50 mW of light may be hitting the page. ~Kaimbridge~ ----- Wikipedia-Contributor Home Page: http://en.wikipedia.org/wiki/User:Kaimbridge ***** Void Where Permitted; Limit 0 Per Customer. ***** |
Converting From mV/m To Decayed mW (ERP)
wrote:
On Jan 24, 2:45 pm, "mpm" wrote: On Jan 23, 8:29?pm, "Kaimbridge" wrote: What I'm interested in is converting a given field strength mV/m, at a given distance for a particular frequency, to the equivalent (decayed) baseline wattage. If I understand what you're asking, your question really centers around how to calculate Free Space Loss. The Friis Equation will allow you to do this, and it is a relatively simple matter to derive Free Space Path Loss in decibel form from the Friis Equation. I'm not su Is this the same (or at least related to) W/m^2? The problem I see with these is that, as distance approaches 0, KW approahes oo and what I'm looking for shouldn't be greater than the transmitter's erp. What got me on this idea, is a few weeks go I was visiting up in the NH White Mountains and was checking out the AM/FM bands (I'm a radio geek! P=). When I got home, I went to the FCC site to create a bandscan of the area. The designation used was the radius from a point. I quickly realized that this was less than ideal, as--using 100 km radius, as an example--100 W stations at that distance would be listed along with 50 and 100 KW! What would be much more useful would be a listing of stations that provide--st least the theoretical baseline value (i.e., not considering intervening local terrain or one's receiver sensitivity and antenna gain)--a given mV/m or mW at that point (thus listing 100 W stations out to 15 km, whereas 50 KW stations out to 75 km and 100 KW to 130 km would be listed). Think of it this way: If you turned on a 100 W lightbulb in the middle of a field at night and held a book page right up to it, you would be able to read it clearly; if you moved about 10 feet away (with the book page still facing the lightblb, unobstructed), you would have difficulty trying to read it, as only about the equivalent of (e.g.) 50 mW of light may be hitting the page. ~Kaimbridge~ ----- Wikipedia-Contributor Home Page: http://en.wikipedia.org/wiki/User:Kaimbridge ***** Void Where Permitted; Limit 0 Per Customer. ***** Unless i am more mistaken than usual, the basic reference distance for radiated power is 1 meter from the phase center of the antenna. Of course depending on wavelength / frequency this could mean sub-near field measurements to normal (semi-far to far field) measurements. -- JosephKK Gegen dummheit kampfen die Gotter Selbst, vergebens.Â*Â* --Schiller |
| All times are GMT +1. The time now is 01:46 AM. |
Powered by vBulletin® Copyright ©2000 - 2025, Jelsoft Enterprises Ltd.
RadioBanter.com