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Freiraum und Mehrwegausbreitung
Theorie und Praxis – Freiraum und Mehrwegausbreitung LOS: Line of Sight NLOS: Non Line of Sight
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Professionelle Messungen
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Kanal Stossantwort
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HSR Rapperswil Campus Measurement Results
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Kanal Frequenzgang FFT h(t) H(f)
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Product News 2012
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CW Messung Nur Pegel Information
Mittelung über Zeit und örtlich lokal ( x Fläche) Gilt streng genommen nur für diese Frequenz Low cost solution: RSSI Anzeige von Funkmodul nutzen Liefert nur Large Scale Model und allenfalls Varianz
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mit Referenzpunkt bei do:
Freiraum - Formel Sendeleistung Gewinn TX-Antenne Gewinn RX-Antenne Wellenlänge Empfangsleistung Distanz in dBm: mit Referenzpunkt bei do: zur Erinnerung:
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Isotropic Antenna for E-field Measurement
X-axis (vertical) Z-axis Y 27 MHz to 3 GHz (UKW till UMTS) Triaxial passive E-Field Antenna Three to each electrical right angelic diploes Very easy to use without the thinking over polarization of the signal Nearly usable for all applications
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Modell “Exponent n” Ansatz: Anpassung des Exponenten n der Kanaldämpfung im Term dn Kanaldämpfung [dB]: darin Anteil Sichtverbindung bis do [dB]: Messtechnischer Ansatz Receive Power [dBm]: darin Anteil Sichtverbindung bis do [dBm]: Messwert bei do oder Rechenwert in dBm: fs: free space
![Modell Exponent n Ansatz: Anpassung des Exponenten n der Kanaldämpfung im Term dn. Kanaldämpfung [dB]:](http://slideplayer.org/slide/2965183/10/images/10/Modell+Exponent+n+Ansatz%3A+Anpassung+des+Exponenten+n+der+Kanald%C3%A4mpfung+im+Term+dn.+Kanald%C3%A4mpfung+%5BdB%5D%3A.jpg "darin Anteil Sichtverbindung bis do [dB]: Messtechnischer Ansatz Receive Power [dBm]: darin Anteil Sichtverbindung bis do [dBm]: Messwert bei do. oder Rechenwert in dBm: fs: free space.")
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Modell “Exponent n”: Wahl von do
Einsatzort do Indoor Office m Indoor Factory m Outdoor Urban m Outdoor Rural m do Beispiel: n = 3.8
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Professionelle Messungen
Helsinki University: Indoor Corridor with LOS
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Matlab Auswertung 1. Enter >>prdb = [ -aa, -bb, ... , -cc]
where aa, bb,… substituting your own measured values of the received power measured on the spectrum analyser, prdb, at each point beginning at do for the sample values shown. 2. Enter >>d = [u, v,...z] where u,v,… is for the distance d do in metres at which you took the values. Ensure that each reading in prdb corresponds to the appropriate value of d. 3. Enter >>plot(10*log10(d),prdb,’g’) and >>hold You should now have a log - log graph of power vs distance. 4. Enter >>plot(10*log10(d),prdb,’+’) and >>grid to add points and a grid to the graph. 5. Enter >>lsline to add a least square line to the points. 6. Enter >>h = polyfit( 10*log10(d), prdb, 1) The vector h returns the slope and y-axis (prdb, i.e., receiver power in dB) intercept of the least square line. The slope corresponds to the path loss exponent n
![Matlab Auswertung 1. Enter >>prdb = [ -aa, -bb, ... , -cc]](http://slideplayer.org/slide/2965183/10/images/13/Matlab+Auswertung+1.+Enter+%3E%3Eprdb+%3D+%5B+-aa%2C+-bb%2C+...+%2C+-cc%5D.jpg "where aa, bb,… substituting your own measured values of the received. power measured on the spectrum analyser, prdb, at each point beginning. at do for the sample values shown. 2. Enter >>d = [u, v,...z] where u,v,… is for the distance d do in metres at which you took the values. Ensure that each reading in prdb corresponds to the appropriate value of d. 3. Enter >>plot(10*log10(d),prdb,’g’) and >>hold. You should now have a log - log graph of power vs distance. 4. Enter >>plot(10*log10(d),prdb,’+’) and >>grid. to add points and a grid to the graph. 5. Enter >>lsline. to add a least square line to the points. 6. Enter >>h = polyfit( 10*log10(d), prdb, 1) The vector h returns the slope and y-axis (prdb, i.e., receiver power in dB) intercept of the least square line. The slope corresponds to the path loss exponent n.")
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Indoor Messdiagramm mit Freifeldreferenz
Distanz m Pegel dBm Slope n=2
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Demo Outdoor Simulation
Free Tool „RADIO MOBILE“
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