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Power divider network for dual-fed adaptive antenna

Published online by Cambridge University Press:  29 March 2022

Serafin B. Fischer*
Affiliation:
University of Stuttgart, 70569 Stuttgart, Germany
Jan Hesselbarth
Affiliation:
University of Stuttgart, 70569 Stuttgart, Germany
*
Author for correspondence: Serafin B.Fischer, E-mail: [email protected]
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Abstract

Exposing the near field of an antenna to varying dielectric environment causes changes of the antenna input impedance and, thus, unwanted feed mismatch. Feeding such an antenna at different points, and selecting an appropriate feed for best match at a given scenario, may solve the problem. For the case of two scenarios of different dielectric environments and an antenna with two feed points, this work presents a passive power divider network, which keeps the antenna matched to the source in either scenario. Specific impedance transformations in the two branches of the divider network realize power transfer in a first scenario from the source to complex feed impedance at the first antenna feed, while in a second scenario, with now different antenna feed impedances, matched power transfer is from the source to the second antenna feed. Analytical formulae are derived for the design of the divider network. An experiment uses an example antenna with two feeds and a microstrip divider network, connected to a common 50 ohm port. Measurements are conducted with the antenna radiating, first, in air and, secondly, into butter. The measurements show antenna match at 1 GHz in either case and agree well with the analytical results.

Type
Passive Components and Circuits
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press in association with the European Microwave Association

Introduction

Nowadays, radio-frequency identification (RFID) techniques are ubiquitous in our daily life, such as in logistics, contactless payment, and medicine. The generic RFID system comprises a mobile device or “tag” and a “reader”. While the “reader” can be positioned in a well-defined environment, the “tag” may be exposed to different environments, for example, different dielectric or metallic properties of materials close to the “tag” antenna. These properties may affect and deteriorate the antenna performance significantly.

An illustrative example is a subcutaneous capsule that generates biomedical data, which are then transmitted, by means of an antenna, to an off-body located “reader”. Depending on the disposition, the dielectric and conductive properties of the antenna environment vary (different composition of skin, muscles, bones, etc.), which results in an input impedance variation of the antenna, mismatch, and finally, reduced communication range. This variation can be compensated by a tunable matching network with adaptive control [Reference Gu and Morris1]. Another possible solution is shown in [Reference Nikolayev, Zhadobov, Karban and Sauleau2], where high-permittivity dielectric cover, which reduces feed impedance variation, encloses the antenna. Quite similarly, a spacer can increase the distance between antenna and body environment, thereby stabilizing feed impedance [Reference Dissanayake, Esselle and Yuc3]. Alternatively, matching can be ensured, while environment of the antenna changes, by selecting a suitable feed of a multiply-fed antenna [Reference Rasteh and Hesselbarth4]. Such selection can be obtained by switching. Yet another method uses the combination of different radiating resonance modes of the antenna for different environment scenarios, as proposed in [Reference Fischer and Hesselbarth5] for the respective scenarios of a metal surface close by the antenna and the antenna in the air.

This work considers an antenna with two feed points, represented by two complex feed impedances. A passive and lossless power divider connects a source to the two antenna feeds (Fig. 1). Now considering two scenarios for the environment of the antenna, the pair of complex feed impedances is largely different for either scenario. The power divider consists of two arms. Each arm provides an impedance transformation, which can be realized, for example, by a transmission line structure. Each arm realizes two transformations according to the two scenarios: In one case, it provides conjugate matching toward the source, while for the other scenario, it transforms the corresponding load impedance into the highest possible impedance. Next, the two arms connect to form a power divider fed by the source. As a result, in one scenario, maximum power is transferred to the first antenna feed, while in the second scenario, maximum power goes to the second antenna feed. In both cases, the overall one-port system is matched to a source impedance of, for example, 50 ohm. In the following, a design procedure for the power divider, based on analytical formulas, is presented.

Fig. 1. Concept of matching a dual-fed antenna to a source by a power divider network (PDN). Varying antenna feed impedances due to environmental (near-field) changes to the antenna cause the power flow to change from connecting feed one with the source in the first scenario, while connecting feed two with the source in the second scenario.

Said operation of the proposed power divider distinguishes it from Wilkinson's divider [Reference Wilkinson6] and its extension for complex load impedances as reported in [Reference Rosloniec7]. Likewise, it is not just a power divider that splits the power unequally, as shown in works [Reference Li and Wang8] and [Reference Lim, Lee, Kim, Park, Ahn and Nam9]. Rather, the proposed power divider concept realizes a particular case of unequal power split, with different splits for two respective sets of complex load impedances at its output ports (i.e. four different, freely-chosen output load impedances). It is optimally adapted to the use case of a dual-fed antenna operating in varying electromagnetic environment.

The proposed technique is fully passive and theoretically lossless, and can be realized in standard transmission line (TL) technology, such as microstrip. Thereby, it is reciprocal, and all statements related to a transmit scenario apply equally to a receiver scenario.

In section “Power divider design”, the power divider design is given. It comprises four subsections. In the first one, a most simplified case is presented which shows the principle. In the second subsection, a lumped element-based TL model is introduced, which is the basis for the impedance transformation network (ITN) given in the third subsection. Two of these ITNs form the two branches of the power divider network (PDN), which is discussed in the fourth subsection. Section “Example” shows an example with experimental verification. Two monopoles with unequal lengths, mounted very close to each other, act as a single, dual-fed antenna. They are fed with the PDN. The last section contains the conclusion, consisting of a summary, a classification of this work with regard to RFID technology, and an outlook on future extensions.

Field simulation results are obtained from the finite-element method-based solver in CST Microwave Studio.

Power divider design

Most simplified case

This section explains the principle of this work in a most simplified case. The circuit of Fig. 2, i.e. just two resistors R 1 and R 2, in parallel with source voltage V i and source resistor R i, is considered. There are two scenarios assumed, where R 1 and R 2 have different values, while R i remains constant. For a particular valueset of R 1 and R 2, which is scenario 1, matching between the source, and the two resistors are obtained. In scenario 2 the values of R 1 and R 2 are interchanged in such a way that the source is still matched to the load. In Fig. 3 the normalized (to the maximum available power of the source) power dissipated in R 1 (red dashed line “p 1”) and in R 2 (blue dotted line “p 2”) are shown. Thereby, the value R 1 varies from 10 to 450 ohm while R 2 varies from 450 to 10 ohm as indicated by the two x-axes. The two vertical solid lines indicate the two scenarios. In addition, the reflected power (black dash-dotted line) is plotted. In these scenarios, the reflected power is zero. In scenario 1 the dissipated power in R 1 = R 1,max (≈ 57 ohm) is 87.6% of the maximum power that the source can deliver. Then, the dissipated power in R 2 = R 2,min (≈ 403 ohm) is 12.4%. In scenario 2 it is the other way around, as can be seen in Fig. 3. Consequently, this behavior can be seen as a natural power switch that flips in dependency on the load. It is also clear that, for a particular scenario, one of the resistors should have a value that is as close as possible to the value of the source resistance. If this is the case, the value of the other resistor must be very high in order to achieve matching.

Fig. 2. Two resistors in parallel.

Fig. 3. Portions of the maximum power, which the source can deliver: reflected power |Γ|2 (black dash-dotted line), the power dissipated in R 1 (p 1 red dashed line) and the power dissipated in R 2 (p 2 blue dotted line).

In this work, a PDN based on TLs is developed which transforms (for both scenarios) two impedances in such a way that for scenario 1 most of the power is transferred to the first complex impedance and for scenario 2 to the second complex impedance. Therefore, it is important to note that in the general case, the four complex loads can be chosen arbitrarily (contrary to the aforementioned most simplified case).

Transmission line model

TLs shall constitute the power divider. For simplicity, lossless TLs are assumed. The approach is based on the well-known equivalent circuit for a TL as given in [Reference Pozar10]. This lumped-element equivalent circuit of a small length of a TL is continued periodically leading again to a lumped-element equivalent circuit and is depicted in Fig. 4(a). It is used to derive the design equations. This circuit comprises a series reactance, a transformer and a shunt reactance. It is equivalent to a TL of length L at a given frequency under conditions of (1).

(1a)$${Z_s} = {\,j}\tan( \beta {L} ) {Z_0} = {\,j X_s}$$
(1b)$${Z_p} = -{\,j}\cot\,( \beta {L} ) {Z_0} = {\,j X_p}$$
(1c)$$\eqalign{{u}& = {\it \rm{sgn}}\left(\cos( \beta{L}) \right)\sqrt{1 + \tan( \beta {L} ) ^2}\cr & = \rm{sgn}\left(\cos( \it \beta{L}) \right)\sqrt{1-{\it {X_s}\over {\it X_p}}} }$$

Here, β denotes the phase constant, u is the transformer's turns ratio and sgn the sign function.

Fig. 4. Lumped-element equivalent circuit model. (a) Circuit model of a transmission line. (b) Circuit model of a two-step transmission line-based impedance transformer.

Impedance transformation network

The impedance transformation network is a series circuit of two TLs (Fig. 4(b)). The load impedance Z L (i.e. antenna feed impedance) can take two different values. It has the following properties: (i) Maximum power transfer through the ITN, with respect to the source impedance Z m, for the load impedance Z L = Z L,max. (ii) Minimum power transfer through the ITN, with respect to the source impedance Z m, for the load impedance Z L = Z L,min. In the first case, if Z L = Z L,max, the ITN provides conjugate-complex match

(2)$${Z_{in}\vert _{{Z_L} = {Z_{L, \max}}}} = {Z^\ast _m}$$

for maximum power transfer. Considering (1) and the circuit of Fig. 4(b), then (2) leads to

(3a)$${X_{\,p, 1}} = x$$
(3b)$${X_{\,p, 2}} = y$$
(3c)$${X_{s, 1}} = {{N_1}\over x{D}}$$
(3d)$${X_{s, 2}} = {{N_2}\over y{D}}$$

with

$$\eqalign{{N_1} & = {Re\{ Z_m-Z_{L, \max}\} }x^2y\cr & \quad-2{Im\{ Z_m\} Re\{ Z_{L, \max}\} }xy\cr & \quad-{Im\{ Z_mZ^\ast _{L, \max}\} }x^2-{Re\{ Z_{L, \max}\} \vert Z_m\vert ^2}\left(x + y\right)\cr {N_2} & = {Re\{ Z_{L, \max}-Z_m\} }xy^2\cr & \quad-2{Im\{ Z_{L, \max}\} Re\{ Z_m\} }xy \cr & \quad + {Im\{ Z_mZ^\ast _{L, \max}\} }y^2-{Re\{ Z_{m}\} \vert Z_{L, \max}\vert ^2}\left(x + y\right)\cr {D}& = {Re\{ Z_{L, \max}\} }x + {Re\{ Z_m\} }y + {Im\{ Z_mZ_{L, \max}\} }}$$

Since (2) leads to two equations (if split in real and imaginary part), but the network itself comprises four parameters, two of them are freely selectable indicated by x and y (with the unit ohm).

It is stated that the input impedance Z in for Z L = Z L,min (i.e. ${Z_{in}\vert _{Z_L = Z_{L, \min }}}$) must be as high as possible to minimize the power in Z L,min. From here, the real part of Z in is considered only, because the imaginary part will be compensated when two ITNs are combined forming the power divider (see subsection “Power divider network”). Figure 5 colormap shows the real part of Z in if the ITN is terminated in Z L,min for different values of x and y. Dark red gives the maximum value, whereas dark blue indicates a low value with the unit ohm. Here, example values for Z L,min and Z L,max are chosen deliberately. It is calculated with (3) and consequently fulfils (2). To find the maximum values, the following equation must be met

(4)$$\nabla_{x, y}( {Re\{ {Z_{in}\vert _{Z_L = Z_{L, \min}}}}\} ) = 0.$$

$\nabla _{x, y}$ indicates the gradient with respect to x and y. Both resulting equations are fulfilled for a certain dependency between x and y

(5)$$x = {{T_1}y^2 + {T_2}y + {T_3}\over {T_4}y^2 + {T_5}y + {T_6}}$$

where terms T i, i = 1,  2,  …,  6 depend on Z m,  Z L,max, and Z L,min and are given in Appendix. Inserting (5) into (3) gives the solution that fulfils the aforementioned properties of the ITN. For the same example of Fig. 5 the relation between x and y of (5) is plotted in Fig. 6. The curve can be recognized in Fig. 5 as the maxima. Furthermore, by using (1), the characteristic impedances as well as the electrical lengths of the two TLs, which form the ITN, can be obtained.

Fig. 5. Colormap of ${Re\{ {Z_{in}\vert _{Z_L = Z_{L, \min }}}}\}$ over x and y (see (3)) with Z L,min = 20 + j10 [Ω] and Z L,max = 70 − j50 [Ω] arbitrarily chosen. This map is calculated with (3). Dark red indicates the maximum value while dark blue gives the minimum value in ohm. It should be noted that for ${Z_{in}\vert _{Z_L = Z_{L, \max }}}$ (2) is fulfilled for all values of x and y.

Fig. 6. Plotted function of (5) for Z L,min = 20 + j10 [Ω] and Z L,max = 70 − j50 [Ω]. This curve gives the relation between x and y to obtain the highest possible value of the real part of ${Z_{in}\vert _{Z_L = Z_{L, \min }}}$. At the same time (2) for ${Z_{in}\vert _{Z_L = Z_{L, \max }}}$ is fulfilled. This curve can be recognized as the maxima of the colormap in Fig. 5.

Power divider network

Two of the ITN described above form a three-port PDN. As shown in Fig. 7(a), the two scenarios (with source and PDN unchanged) have different loads, Z L1 and Z L2. These loads are transformed through the ITNs, and the simplified circuits of Fig. 7(b) are obtained. Here, the subscript “max” indicates the load where the dissipated power is maximized, and the subscript “min” indicates the load where the dissipated power is minimized. For example, Z in,max denotes the input impedance of the ITN connected to the load Z L = Z L,max for the scenario where the maximum power should be delivered to this load. From the circuits of Fig. 7(b), conjugate-complex match to the source impedance Z i gives

(6a)$$Z^\ast _i = {Z_{in1, \max}Z_{in2, \min}\over Z_{in1, \max} + Z_{in2, \min}}$$
(6b)$$Z^\ast _i = {Z_{in1, \min}Z_{in2, \max}\over Z_{in1, \min} + Z_{in2, \max}}$$

which can be written as

(7a)$$Z_{in1, \max} = Z^\ast _{m1} = {Z^\ast _i Z_{in2, \min}\over Z_{in2, \min}-Z^\ast _i}$$
(7b)$$Z_{in2, \max} = Z^\ast _{m2} = {Z^\ast _i Z_{in1, \min}\over Z_{in1, \min}-Z^\ast _i}$$

Fig. 7. The scheme of the power divider network (PDN). (a) An illustration of the PDN comprising two impedance transformation networks (ITN) in parallel with its two scenarios. (b) The equivalent circuit of the PDN with its two scenarios.

The two equations of (7) have unknowns Z in1,max, Z in2,max, Z in1,min, Z in2,min. In addition, (2) and (4) relate Z in,max and Z in,min for each of the two ITNs. Therefore, this system of equations can be solved numerically and parameters of the TLs can be calculated.

The PDN presented here is a way of solving the problem of two different environments around an antenna. Intuitively, an alternative approach would be to use only one feed point of the antenna which is then matched with only one ITN for two load impedances (two different environments). However, the design of such a network is not straightforward due to the impedance matching domain problem as discussed in [Reference Sun and Fidler11] for LC ladder networks. Thus, this single-feed approach is not suitable for a generalized case. On the other hand, the proposed dual-fed approach is straightforward, as shown in the following example.

Example

The procedure developed in section “Power divider design” is applied to a practical example of an adaptive antenna. The idea is to use the PDN to feed two monopoles (diameter of 2 mm) of different length, very close to each other (≈ λ/15) at 1 GHz (Fig. 8(a)). Here, “M1” indicates monopole 1 (length 72 mm ≈ λ/4) and “M2” monopole 2 (length 35 mm ≈ 0.116λ). In the first scenario, the monopoles are placed in free space. In the second scenario, the monopoles are fully immersed in a lossy organic material (namely, butter). This example setup of the two coupled monopole antenna was chosen because it allows for an easy and clear separation of the electromagnetic environment of the antenna (namely, “air” versus “butter”) from the PDN (the microstrip circuit in the opposite side of the antenna ground plane). The PDN matches the monopoles, in both scenarios, to a single 50 ohm source. From inspection of field simulation field plots, it can be noted that in the first scenario (free space), most of the power is radiated via the first monopole, while in the second scenario (butter), mostly the second monopole radiates.

Fig. 8. (a) Two monopoles of different length next to each other forming the dual-fed adaptive antenna. (b) Photo of the butter-filled cylindrical resonator (opened for clarity) for determination of the material properties of butter.

The dielectric properties of butter are measured. Transmission through a cylindrical cavity resonator, at first air-filled and then filled with butter (Fig. 8(b)), is measured and modeled in a field simulator, allowing to obtain permittivity and loss tangent by fitting. Permittivity ɛ r,butter = 4.13 and tanδbutter = 0.04 is found at 1 GHz.

Field simulation provides the respective input impedances for the two monopoles M1, M2 for the two scenarios, as listed in Table 1 under notation “1st simulation”. The indices are chosen such that M1 is primarily fed to radiate in the free-space scenario, whereas M2 is primarily fed to radiate in the “butter scenario”. For illustration, Fig. 9 shows plots of the variation of the monopole input impedances while linearly varying permittivity and loss tangent from the values of the first scenario to their values of the second scenario. It should be noted that strong coupling between the two monopoles (also expected for most dual-fed antenna structures) leads to some change of feed impedance of one monopole while the other monopole's feed is connected to a varying load (active impedance). The PDN is derived from the impedances, which in turn are obtained from a field simulation assuming simple, e.g. 50 ohm, port impedance. This PDN, however, then provides different impedances to the antenna, changing the active impedances of the antenna network at its ports. In an iterative procedure, these updated antenna impedances allow to derive an updated PDN. This process converges quickly. Note that additional field simulations are not required, as the scattering parameter matrix (or impedance matrix) of the antenna (for each scenario) needs to be obtained only at the beginning.

Fig. 9. Simulated input impedance of the two monopoles when assuming a linear transition of the relative permittivity and loss tangent from the scenario with air to the one with butter. It holds Z L1r = 1,  tanδ = 0) = Z L1,max, Z L2(1,  0) = Z L1,min, Z L1(4.13,  0.04) = Z L1,min, and Z L2(4.13,  0.04) = Z L2,max.

Table 1. Simulated input impedances of the monopoles

Table 1 lists under notation “converged” the respective input impedances of the two monopoles M1, M2 for the two scenarios. Using the input impedances of Table 1, equations (1)–(7) permit the calculation of impedances and electrical lengths of the TLs forming the ITNs (Fig. 10, Table 2). These calculations are executed with Matlab. For each ITN, a remaining degree of freedom allows to select one parameter. In this example, the parameter y = −5 ohm is chosen for each ITN (this choice is governed by the resulting, “realizable” TL impedances).

Fig. 10. Equivalent circuit of the PDN.

Table 2. Characteristic impedances and electrical lengths of the PDN transmission lines for y = −5 Ω

Table 2 lists the obtained parameters of the TLs of the PDN. The values for the PDN of the first iteration (notation “1st simulation”) do not differ much from the values obtained from the converged iterative design process (notation “converged”). In particular, in a practical realization of the PDN in microstrip technology, the differences will be negligible. However, for an even-stronger coupling between the ports of the dual-fed antenna, the changes during the iterative design procedure may become larger.

In Fig. 11 the simulated (here, TLs are lossless) portions of the maximum power that can be delivered from the source of the reflected power |Γ|2 (black dash-dotted line), the power dissipated in Re{Z L1} (p 1 red dashed line), and the dissipated power in Re{Z L2} (p 2 blue dotted line) are plotted. Thereby, the input impedance changes over the relative permittivity and the loss tagent is considered (see Fig. 9). In the air-scenario, 99.8% of the maximum power is consumed by monopole M1, while only 0.2% is dissipated in monopole M2. If the monopoles are exposed in butter, the reflected power is about 0.2%, the power in M1 is 9.5%, and in M2 is 90.3%.

Fig. 11. Simulated portions of the maximum power of the reflected power |Γ|2 (black dash-dotted line), the power dissipated in Re{Z L1} (p 1, red dashed line) and dissipated power in Re{Z L2} ( p 2, blue dotted line) over different valuesets of the relative permittivity and the loss tangent. In the scenario where the monopoles are placed in air (ɛ r = 1, tanδ = 0) the reflected power is zero and the dissipated power p 1 in Re{Z L1} is about 99.8% of the maximum power that can be delivered from the source. Then the power p 2 in Re{Z L2} is 0.2%. In the scenario of butter (ɛ r = 4.13, tanδ = 0.04) |Γ|2 is 0.2%, p 1 is 90.3%, and p 2 is 9.5%.

So far, optimum operation was required at two different scenarios, as illustrated in Fig. 11, showing the reflected power at source becoming zero for ɛ r = 1 and ɛ r = 4.13. A modification of the use-case may require good performance (i.e. small reflected power) over a range of dielectric property of the electromagnetic environment. Such use-case may represent somewhat varying material property and/or varying geometry of the environment of the antenna, as it can be expected for many RFID-like applications.

Exposing the pair of coupled monopole radiators to three other pairs of environmental dielectric scenarios, Fig. 12 illustrates the simulated resulting reflection coefficient magnitude. The four permittivity-pairs related to Fig. 12 are: (i) ɛ r = {1,  4.13}, (ii) ɛ r = {1.5,  3.5}, (iii) ɛ r = {2,  3}, (iv) ɛ r = {2.25,  2.75}. Obviously, the dielectric property of the electromagnetic environment can always vary by a small amount, without resulting in large mismatch. Once the two “optimally matched” permittivity values are close-enough to each other (as in cases (iii) and (iv)), a range of electromagnetic environment, leading well-matched input impedance, is obtained. Similar behavior is common to any ITN.

Fig. 12. Simulated reflection coefficient |Γ| in dB for the two-monopole-antenna with four different PDNs, corresponding to four pairs of environmental scenarios to the antenna. Case (i): ɛ r = {1,  4.13} in black dash-dotted line. Case (ii): ɛ r = {1.5,  3.5} in red dashed line. Case (iii): ɛ r = {2,  3} in blue dotted line. Case (iv): ɛ r = {2.25,  2.75} in green solid line. The associated loss tangent (tanδ) values are scaled proportionally.

The microstrip line parameters are readily found for the circuit realized on Rogers RT6002 substrate (thickness 0.762 mm, ɛ rel = 2.94, tanδ = 0.0012). Figure 13 shows the realization of the two monopole radiators and the PDN on a microstrip circuit board. The ground layer has openings of 4 mm diameter for the monopoles. The monopole metal rods pass through the board and are soldered to the microstrip traces. The feed reflection magnitude at the coax connector, measured for the two scenarios, is shown in Fig. 14. Good match is achieved for both scenarios (free-space and butter). Furthermore, the measured curves are in good agreement with the field simulations.

Fig. 13. Adaptive antenna prototype. Left: two monopoles over board ground. Right: microstrip PDN and feed.

Fig. 14. Measured and simulated reflection coefficient of the adaptive antenna for both scenarios (air and butter). The inset picture shows the measurement setup for the scenario with butter.

Conclusion

Analytical formulae for a power divider feed network for a dual-fed antenna are presented. If the antenna operates in two electromagnetically different environments, called scenarios, its feed impedances will change. The proposed power divider feed network directs the power from a matched source to the first antenna feed in the first scenario, and to the second antenna feed in the second scenario. The proposed power divider feed network is passive and assumed lossless. In a practical demonstration, two strongly coupled monopole radiators of largely different length are fed by an accordingly designed power divider feed network. This structure radiates with perfect source match (50 ohm) into free space, but also when completely immersed into butter (ɛrbutter = 4.13, tanδbutter = 0.04). The measurements confirm the derived theoretical formulae.

The presented PDN can be used with RFID tags to adapt the antenna to two different environments. It ensures an energy-efficient operation of the RFID tag without much power being reflected at the antenna input.

From a theoretical point of view, the number of different environmental scenarios, as well as the number of antenna feed points, can both be increased to a number larger than two. If N scenarios shall be covered with an antenna having N feed points, then the extension of the approach discussed in this paper (here N = 2) shows that each of the N arms of the power divider requires N sections of TL to realize the appropriate impedance transformation. However, already for N = 3, these nine lines contribute to loss and increase the physical size of the circuit likely beyond a practical limit.

Acknowledgments

This work was supported in part by the German Research Foundation (DFG) under grant HE6429/7-2.

Appendix

Six coefficients T i, i = 1,  2,  …,  6 appear in (5). Their explicit expression read:

(A.1)$$\eqalign{{T_1} & = {Re\{ Z_m\} }\big({Re\{ Z_{L, \min}\} ^2}-{Re\{ Z_{L, \max}\} ^2} \cr & \quad + \big({Im\{ Z_{L, \min}\} }-{Im\{ Z_{L, \max}\} }\big)^2 + {\sqrt{A}}\big)\cr & \quad + 2{Im\{ Z_{m}\} Re\{ Z_{L, \max}\} }\big({Im\{ Z_{L, \min}\} }\cr & \quad-{Im\{ Z_{L, \max}\} }\big)}$$
(A.2)$$\eqalign{{T_2} & = 2{\vert Z_{L, \max}\vert ^2}\big({Im\{ Z_{L, \max}Z^\ast _m\} } \cr & \quad-2{Re\{ Z_m\} Im\{ Z_{L, \min}\} }\big)\cr & \quad + 2{\vert Z_{L, \min}\vert ^2Im\{ Z_mZ_{L, \max}\} } \cr & \quad + 2{Im\{ Z_{L, \max}\} Re\{ Z_m\} \sqrt{A}}}$$
(A.3)$$\eqalign{{T_3} & = {Re\{ Z_m\} \vert Z_{L, \max}\vert ^4} \cr & \quad-{Re\{ Z_m\} Re\{ Z^2_{L, \max}\} \vert Z_{L, \min}\vert ^2} \cr & \quad + {Re\{ Z_m\} \sqrt{A}\vert Z_{L, \max}\vert ^2}\cr & \quad-2{Re\{ Z_m\} Im\{ Z_{L, \min}\} Im\{ Z_{L, \max}\} \vert Z_{L, \max}\vert ^2} \cr & \quad-2{Im\{ Z_m\} Re\{ Z_{L, \max}\} \big(Im\{ Z_{L, \min}\} \vert Z_{L, \max}\vert ^2} \cr & \quad-{Im\{ Z_{L, \max}\} \vert Z_{L, \min}\vert ^2}\big)}$$
(A.4)$$\eqalign{{T_4} & = 2{Re\{ Z_{L, \max}\} \big(Im\{ Z_{L, \max}\} }-{Im\{ Z_{L, \min}\} \big)}}$$
(A.5)$${T_5} = 2{Re\{ Z_{L, \max}\} \big(\vert Z_{L, \max}\vert ^2-\vert Z_{L, \min}\vert ^2\big)}$$
(A.6)$$\eqalign{{T_6} & = 2{Re\{ Z_{L, \max}\} \big(Im\{ Z_{L, \min}\} \vert Z_{L, \max}\vert ^2}\cr & \quad-{Im\{ Z_{L, \max}\} \vert Z_{L, \min}\vert ^2\big)} }$$

with

$$\eqalign{{A} & = \big({Im\{ Z_{L, \min}\} -Im\{ Z_{L, \max}\} }\big)^4 \cr & \quad + \big({Re\{ Z_{L, \min}\} ^2-Re\{ Z_{L, \max}\} ^2}\big)^2 + 2\big({Re\{ Z_{L, \min}\} ^2} \cr & \quad + {Re\{ Z_{L, \max}\} ^2}\big)\big({Im\{ Z_{L, \min}\} }-{Im\{ Z_{L, \max}\} }\big)^2}$$

Serafin B.Fischer was born in Buchholz in der Nordheide, Germany, in 1991. He received the B.Sc. and M.Sc. degrees in electrical engineering from the University of Stuttgart, Germany in 2016 and 2018, respectively. He is currently pursuing the Ph.D. degree at the University of Stuttgart, Stuttgart, Germany. His current research interests include matching networks, adaptive antennas, and antenna-arrays.

Jan Hesselbarth (A’96–M’04) was born in Dresden, Germany, in 1970. He received the Ph.D. degree from the Swiss Federal Institute of Technology (ETH), Zurich, Switzerland, in 2002. From 2001 to 2005, he was a Design Engineer with Huber+Suhner, Pfaffikon, Switzerland. From 2005 to 2008, he was a Technical Staff Member with Bell Laboratories, Dublin, Ireland. He was a Senior Researcher and Lecturer with ETH Zurich. Since 2011, he has been a Professor with the Institute of Radio Frequency Technology, University of Stuttgart, Stuttgart, Germany. His current research interests include antennas and millimeter-wave circuits and packaging.

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Figure 0

Fig. 1. Concept of matching a dual-fed antenna to a source by a power divider network (PDN). Varying antenna feed impedances due to environmental (near-field) changes to the antenna cause the power flow to change from connecting feed one with the source in the first scenario, while connecting feed two with the source in the second scenario.

Figure 1

Fig. 2. Two resistors in parallel.

Figure 2

Fig. 3. Portions of the maximum power, which the source can deliver: reflected power |Γ|2 (black dash-dotted line), the power dissipated in R1 (p1 red dashed line) and the power dissipated in R2 (p2 blue dotted line).

Figure 3

Fig. 4. Lumped-element equivalent circuit model. (a) Circuit model of a transmission line. (b) Circuit model of a two-step transmission line-based impedance transformer.

Figure 4

Fig. 5. Colormap of ${Re\{ {Z_{in}\vert _{Z_L = Z_{L, \min }}}}\}$ over x and y (see (3)) with ZL,min = 20 + j10 [Ω] and ZL,max = 70 − j50 [Ω] arbitrarily chosen. This map is calculated with (3). Dark red indicates the maximum value while dark blue gives the minimum value in ohm. It should be noted that for ${Z_{in}\vert _{Z_L = Z_{L, \max }}}$ (2) is fulfilled for all values of x and y.

Figure 5

Fig. 6. Plotted function of (5) for ZL,min = 20 + j10 [Ω] and ZL,max = 70 − j50 [Ω]. This curve gives the relation between x and y to obtain the highest possible value of the real part of ${Z_{in}\vert _{Z_L = Z_{L, \min }}}$. At the same time (2) for ${Z_{in}\vert _{Z_L = Z_{L, \max }}}$ is fulfilled. This curve can be recognized as the maxima of the colormap in Fig. 5.

Figure 6

Fig. 7. The scheme of the power divider network (PDN). (a) An illustration of the PDN comprising two impedance transformation networks (ITN) in parallel with its two scenarios. (b) The equivalent circuit of the PDN with its two scenarios.

Figure 7

Fig. 8. (a) Two monopoles of different length next to each other forming the dual-fed adaptive antenna. (b) Photo of the butter-filled cylindrical resonator (opened for clarity) for determination of the material properties of butter.

Figure 8

Fig. 9. Simulated input impedance of the two monopoles when assuming a linear transition of the relative permittivity and loss tangent from the scenario with air to the one with butter. It holds ZL1r = 1,  tanδ = 0) = ZL1,max, ZL2(1,  0) = ZL1,min, ZL1(4.13,  0.04) = ZL1,min, and ZL2(4.13,  0.04) = ZL2,max.

Figure 9

Table 1. Simulated input impedances of the monopoles

Figure 10

Fig. 10. Equivalent circuit of the PDN.

Figure 11

Table 2. Characteristic impedances and electrical lengths of the PDN transmission lines for y = −5 Ω

Figure 12

Fig. 11. Simulated portions of the maximum power of the reflected power |Γ|2 (black dash-dotted line), the power dissipated in Re{ZL1} (p1, red dashed line) and dissipated power in Re{ZL2} ( p2, blue dotted line) over different valuesets of the relative permittivity and the loss tangent. In the scenario where the monopoles are placed in air (ɛr = 1, tanδ = 0) the reflected power is zero and the dissipated power p1 in Re{ZL1} is about 99.8% of the maximum power that can be delivered from the source. Then the power p2 in Re{ZL2} is 0.2%. In the scenario of butter (ɛr = 4.13, tanδ = 0.04) |Γ|2 is 0.2%, p1 is 90.3%, and p2 is 9.5%.

Figure 13

Fig. 12. Simulated reflection coefficient |Γ| in dB for the two-monopole-antenna with four different PDNs, corresponding to four pairs of environmental scenarios to the antenna. Case (i): ɛr = {1,  4.13} in black dash-dotted line. Case (ii): ɛr = {1.5,  3.5} in red dashed line. Case (iii): ɛr = {2,  3} in blue dotted line. Case (iv): ɛr = {2.25,  2.75} in green solid line. The associated loss tangent (tanδ) values are scaled proportionally.

Figure 14

Fig. 13. Adaptive antenna prototype. Left: two monopoles over board ground. Right: microstrip PDN and feed.

Figure 15

Fig. 14. Measured and simulated reflection coefficient of the adaptive antenna for both scenarios (air and butter). The inset picture shows the measurement setup for the scenario with butter.