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Berkeley ELENG 290Q - A Near Field Propagation Law

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Hans Gregory Schantz ([email protected]) The Q-Track Corporation; 515 Sparkman Drive; Huntsville, AL 35816ABSTRACTPreprint – Submitted to IEEE APS Conference July 2005; © 2005 Dr. Hans Schantz A Near Field Propagation Law & A Novel Fundamental Limit to Antenna Gain Versus Size Hans Gregory Schantz ([email protected]) The Q-Track Corporation; 515 Sparkman Drive; Huntsville, AL 35816 ABSTRACT This paper presents a theoretical analysis of the near field channel in free space. Then this paper validates the theoretical model by comparison to data measured in an open field. The results of this paper are important for low frequency RF systems, such as those operating at short range in the AM broadcast band. Finally this paper establishes a novel fundamental limit for antenna gain versus size. 1. INTRODUCTION The “leading edge” of RF practice moves to increasingly higher and higher frequency in lock step with advances in electronics technology. The most commercially significant RF systems are those operating at microwave frequencies and above, such as cellular telephones and wireless data networks. Microwave frequencies have the advantage of short wavelengths, making antenna design relatively straightforward, and vast expanses of spectrum, making large bandwidth, high data rate transmissions possible. There are many applications, however, that do not require large bandwidths. These include real time locating systems (RTLS) and low data rate communications systems, such as hands free wireless mikes or other voice or low data rate telemetry links. For applications like these, lower frequencies have great utility. Lower frequencies tend to be more penetrating than higher frequencies. Lower frequencies tend to diffract around objects that would block higher frequencies. Lower frequencies are less prone to multipath. An amazing and often overlooked world of RF phenomena lies within about a half wavelength of an electrically small antenna. This realm is known as the “near field zone.” The near field zone is usually neglected by RF scientists and engineers because typical RF links operate at distances of many wavelengths where near field effects are utterly insignificant. “Near field” means different things in different contexts. Fortunately there is an excellent article available that sorts through the various definitions of near field and provides some guidance [1]. The present discussion, takes the near field zone as the region within about a half wavelength of an electrically small antenna. The aim of the present paper is to derive a near field propagation equation. This paper compares the near field propagation equation to data obtained in an open field environment. Finally, this near field propagation equation is used to derive a fundamental limit for antenna size versus gain. 2. PATH GAIN IN FAR AND NEAR FIELD This section will discuss the path gain for traditional far field links and summarize the differences between far field and near field links. Then, this section will present a recently introduced a near field link equation that provides path loss for low frequency near field links [2]. The path gain (P) defines the relationship between transmitted power (PTX) and received power (PRX) in a far-field RF link. This relation was first given by Harald Friis [3]: ()() ()2222144,kdGGdGGPPdfPRXTXRXTXTXRX=πλ== (1) In this formula, GRX and GTX are the receive and transmit antenna gains (respectively), d is the distance between the antennas, λ is wavelength, and k = 2π/λ is the wave number. The reason for writing Friis’s law in a non-standard way (using wave number) will become clear momentarily. The upshot of Friis’s Law is that the far-field power rolls off as the inverse square of the distancePreprint – Submitted to IEEE APS Conference July 2005; © 2005 Dr. Hans Schantz (1/d2). Near-field links do not obey this relationship. Near field power rolls off as powers higher than inverse square, typically inverse fourth (1/d4) or higher. This near field behavior has several important consequences. First, the available power in a near field link will tend to be much higher than would be predicted from the usual far-field, Friis’s Law relationship. This means a higher signal-to-noise ratio (SNR) and a better performing link. Second, because the near-fields have such a rapid roll-off, range tends to be relatively finite and limited. Thus, a near-field system is less likely to interfere with another RF system outside the operational range of the near-field system. Electric and magnetic fields behave differently in the near field, and thus require different link equations. Reception of an electric field signal requires an electric antenna, like a whip or a dipole. Reception of a magnetic field signal requires a magnetic antenna, like a loop or a loopstick. The received signal power from a co-polarized electric antenna is proportional to the time average value of the incident electric field squared. For the case of a small electric dipole transmit antenna radiating in the azimuthal plane and being received by a vertically polarized electric antenna, the received power is: () () ()+−6422)(111~~kdkdkdPERXE (2) Similarly, the received signal power from a co-polarized magnetic antenna is proportional to the time average value of the incident magnetic field squared: () ()+422)(11~~kdkdPHRXH (3) in (Thus, the “near field” path gain formulas are: ()()() () ()+−==642)(1114,kdkdkdGGPPfdPERXTXTXERXE (4) for the electric field signal, and: ()() ()+==42)(114,kdkdGGPPfdPRXTXTXHRXH(5) Near Field Channel Model (Electric TX Antenna)-30-20-100102030405060700.01 0.1 1Range (λ)Path Ga dB)E-FieldH-FieldFar Field60 dB/decade40 dB/decade20 dB/decade20 dB/decadeFigure 1 Path gain of a typical near field channel for the magnetic field signal. Equation 4 is the propagation law for like antennas (electric to electric or magnetic to magnetic) and Equation 5 is the near field propagation law for unlike antennas (magnetic to electric or electric to magnetic). Typical path gain in a near field channel is on the order of –6 dB. At very short ranges, path gain may be on the order of +60 dB or more. At an extreme range of about one wavelength the path gain may be about –18 dB. This behavior is summarized in Figure 1. 3. PROPAGATION DATA The Q-Track Corporation


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Berkeley ELENG 290Q - A Near Field Propagation Law

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