Antenna loaded with electromechanical resonators

Abstract

An antenna system having at least one active element with a first end thereof for connection to a radio receiver, transmitter or transceiver and at least one electromechanical resonator connected in series with (i) at least portion of said at least one active element and at least another portion of said at least one active element or (ii) said at least one active element and said radio receiver, transmitter or transceiver. The at least one active element exhibits capacitive reactance at an intended frequency of operation and the at least one electromechanical resonator exhibits inductive reactance at the intended frequency of operation, the inductive reactance of the at least one electromechanical resonator offsetting or partially offsetting the capacitive reactance of the at least one antenna element at the intended frequency of operation.

Claims

1. An antenna system comprising: a. at least one active element having a first end for connection to a radio receiver, transmitter or transceiver; and b. at least one electromechanical resonator connected in series between at least one portion of said at least one active element and at least another portion of said at least one active element, wherein the at least one electromechanical resonator exhibits both a series resonance and a parallel resonance, wherein one of said series and parallel resonances is at a frequency higher than an intended frequency of operation of the antenna system and the other of said series and parallel resonances is at a frequency lower than an intended frequency of operation of the antenna system.

2. The antenna system of claim 1 wherein said at least one active element of the antenna system exhibits capacitive reactance at the intended frequency of operation of the antenna system and wherein said at least one electromechanical resonator exhibits inductive reactance at the intended frequency of operation of the antenna system, the inductive reactance of the at least one electromechanical resonator offsetting or substantially offsetting the capacitive reactance of the at least one antenna element at the intended frequency of operation of the antenna system.

3. The antenna system of claim 2 wherein the electromechanical resonator is not resonant at the intended frequency of operation of the antenna system.

4. An antenna system comprising: a. at least one active element having a first end for connection to a radio receiver, transmitter or transceiver; and b. at least one electromechanical resonator connected in series between at least one portion of said at least one active element and at least another portion of said at least one active element, said at least one active element of the antenna system exhibits capacitive reactance at an intended frequency of operation and wherein said at least one electromechanical resonator exhibits inductive reactance at the intended frequency of operation, the inductive reactance of the at least one electromechanical resonator offsetting or substantially offsetting the capacitive reactance of the at least one antenna element at the intended frequency of operation, said at least one active element of the antenna system also exhibits both a series resonance and parallel resonance, the series and parallel resonances having different resonant frequencies and wherein the electromechanical resonator is not resonant at an intended frequency of operation of the antenna system wherein one of said series and parallel resonances is at a frequency higher than an intended frequency of operation of the antenna system and the other of said series and parallel resonances is at a frequency lower than an intended frequency of operation of the antenna system.

5. The antenna system of claim 1 wherein said at least one electromechanical resonator comprises a two dimensional array of electromechanical resonators.

6. The antenna system of claim 1 wherein said at least one electromechanical resonator comprises a plurality of electromechanical resonators connected in series with different portions of said at least one active element.

7. The antenna system of claim 6 wherein each of said plurality of electromechanical resonators is tuned to present a positive reactance for cancelling (or at least partially offsetting) a capacitive reactance of the at least one active element.

8. The antenna system of claim 7 wherein the resonator exhibiting at frequencies between the series resonance and the parallel resonance a positive reactance thereby causing the electromechanical resonator to effectively behave like an inductor over a frequency range between said series and parallel resonance frequencies.

9. The antenna system of claim 1 wherein antenna system in use operates over a frequency range between the series resonance and the parallel resonance of said at least one electromechanical resonator.

10. An antenna system comprising: at least one active element having a first end for connection to a radio receiver, transmitter or transceiver; and at least one electromechanical resonator connected in series between at least one portion of said at least one active element and at least another portion of said at least one active element wherein said at least one electromechanical resonator comprises a first electromechanical resonator connected in series between at least a portion of said at least one active element and at least another portion of said at least one active element, the first electromechanical resonator having both series and parallel resonance frequencies, the first electromechanical resonator exhibiting at frequencies between the series and parallel resonance frequencies a positive reactance thereby causing the first electromechanical resonator to effectively behave like an inductor over a frequency range between said series and parallel resonance frequencies, the positive reactance of the first electromechanical resonator offsetting or at least partially offsetting a negative reactance of said at least one active element.

11. An antenna system comprising: at least one active element having a first end for connection to a radio receiver, transmitter or transceiver; at least one electromechanical resonator connected in series between at least one portion of said at least one active element and at least another portion of said at least one active element; and further including at least one additional electromechanical resonator connected in series between said at least one active element and said radio receiver, transmitter or transceiver, the at least one additional electromechanical resonator exhibiting both a series resonance and a parallel resonance, wherein one of said series and parallel resonances is at a frequency higher than an intended frequency of operation of the antenna system and the other of said series and parallel resonances is at a frequency lower than an intended frequency of operation of the antenna system.

12. The antenna system of claim 1 wherein said at least one electromechanical resonator comprises at least one electromechanical resonator selected from the group consisting of tuning fork resonators, shear mode resonators, extensional mode resonators and Bulk Acoustic Wave resonators.

13. The antenna system of claim 1 wherein said at least one electromechanical resonator comprises a Micro Electro-Mechanical System (MEMS) device.

14. The antenna system of claim 1 wherein said at least one electromechanical resonator includes a piezoelectric crystal for coupling applied voltages to mechanical modes and wherein the piezoelectric crystal is selected from the group consisting of quartz, AlN or LiNbO.sub.3.

15. An antenna system comprising: at least one active element having a first end for connection to a radio receiver, transmitter or transceiver; and at least one electromechanical resonator connected in series between at least one portion of said at least one active element and at least another portion of said at least one active element, wherein at VLF and LF bands tuning fork resonators are utilized for said at least one electromechanical resonator, while at MF and HF bands extensional mode resonators are utilized for said at least one electromechanical resonator, while at VHF and UHF frequencies shear mode resonators are utilized for said at least one electromechanical resonator and while at L- to C-band frequencies Bulk Acoustic Wave resonators are utilized for said at least one electromechanical resonator.

16. An antenna system comprising: a. at least one active or driven element having a first end for connection to a radio receiver, transmitter or transceiver said at least one active or driven element of the antenna system exhibits capacitive reactance at an intended frequency of operation; and b. at least one piezoelectric crystal type electromechanical resonator connected in series between said at least one active or driven element and said radio receiver, transmitter or transceiver wherein the at least one piezoelectric crystal type electromechanical resonator exhibits both a series resonance and parallel resonance, the series and parallel resonances having different resonant frequencies and wherein one of said series and parallel resonances is at a frequency higher than an intended frequency of operation of the antenna system and the other of said series and parallel resonances is at a frequency lower than an intended frequency of operation of the antenna system.

17. The antenna system of claim 16 wherein said at least one active or driven element of the antenna system exhibits capacitive reactance at an intended frequency of operation and wherein said at least one piezoelectric crystal type electromechanical resonator exhibits inductive reactance at the intended frequency of operation, the inductive reactance of the at least one piezoelectric crystal type electromechanical resonator offsetting or substantially offsetting the capacitive reactance of the at least one antenna element at the intended frequency of operation.

18. The antenna system of claim 17 wherein the electromechanical resonator is not resonant at an intended frequency of operation of the antenna system.

19. The antenna system of claim 16 wherein said at least one piezoelectric crystal type electromechanical resonator comprises a two dimensional array of piezoelectric crystal type electromechanical resonators.

20. The antenna system of claim 16 wherein said at least one piezoelectric crystal type electromechanical resonator includes a plurality of piezoelectric crystal type electromechanical resonators connected in series between different portions of said at least one active element.

21. The antenna system of claim 20 wherein each of said plurality of piezoelectric crystal type electromechanical resonators is tuned to present a positive reactance for cancelling (or at least partially offsetting) a capacitive reactance of the at least one active element.

22. An antenna system comprising: at least one active or driven element having a first end for connection to a radio receiver, transmitter or transceiver said at least one active or driven element of the antenna system exhibits capacitive reactance at an intended frequency of operation; and at least one piezoelectric crystal type electromechanical resonator connected in series between said at least one active or driven element and said radio receiver, transmitter or transceiver, wherein each of said plurality of piezoelectric crystal type electromechanical resonators has both series and parallel resonance frequencies, the resonator exhibiting at frequencies between the series and parallel resonance frequencies a positive reactance thereby causing the electromechanical resonator to effectively behave like an inductor over a frequency range between said series and parallel resonance frequencies and wherein antenna system in use operates over said frequency range between the series and parallel resonance frequencies of each of said electromechanical resonators.

23. The antenna system of claim 16 wherein said at least one piezoelectric crystal type electromechanical resonator includes an additional piezoelectric crystal type electromechanical resonator connected in series between at least a portion of said at least one active or driven element and at least another portion of said at least one active or driven element, the additional piezoelectric crystal type electromechanical resonator having both series and parallel resonance frequencies, the additional piezoelectric crystal type electromechanical resonator exhibiting at frequencies between the series and parallel resonance frequencies a positive reactance thereby causing the additional piezoelectric crystal type electromechanical resonator to effectively behave like an inductor over a frequency range between said series and parallel resonance frequencies, the positive reactance of the additional piezoelectric crystal type electromechanical resonator offsetting or at least partially offsetting a negative reactance of said at least one active or driven element.

24. The antenna system of claim 16 further including at least one additional piezoelectric crystal type electromechanical resonator connected in series between said at least one active or driven element and said radio receiver, transmitter or transceiver.

25. The antenna system of claim 16 wherein said at least one piezoelectric crystal type electromechanical resonator comprises at least one piezoelectric crystal type electromechanical resonator selected from the group consisting of tuning fork resonators, shear mode resonators, extensional mode resonators and Bulk Acoustic Wave resonators.

26. The antenna system of claim 16 wherein said at least one piezoelectric crystal type electromechanical resonator comprises a Micro Electro-Mechanical System (MEMS) device.

27. The antenna system of claim 16 wherein said at least one piezoelectric crystal type electromechanical resonator includes a piezoelectric crystal for coupling applied voltages to mechanical modes and wherein the piezoelectric crystal is selected from the group consisting of quartz, AlN or LiNbO.sub.3.

28. An antenna system comprising: at least one active or driven element having a first end for connection to a radio receiver, transmitter or transceiver said at least one active or driven element of the antenna system exhibits capacitive reactance at an intended frequency of operation; and at least one piezoelectric crystal type electromechanical resonator connected in series between said at least one active or driven element and said radio receiver, transmitter or transceiver; wherein at VLF and LF bands tuning fork resonators are utilized for said at least one piezoelectric crystal type electromechanical resonator, while at MF and HF bands extensional mode resonators are utilized for said at least one piezoelectric crystal type electromechanical resonator, while at VHF and UHF frequencies shear mode resonators are utilized for said at least one piezoelectric crystal type electromechanical resonator and while at L- to C-band frequencies Bulk Acoustic Wave resonators are utilized for said at least one piezoelectric crystal type electromechanical resonator.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1a depicts an electrically short dipole antenna loaded with an electromechanical resonator.

(2) FIG. 1b depicts an electrically short dipole antenna loaded with two electromechanical resonators.

(3) FIG. 1c depicts an electrically short monopole antenna loaded with an electromechanical resonator.

(4) FIG. 2a depicts an embodiment of an electromechanical resonator, this particular embodiment being a quartz shear mode Micro Electro-Mechanical System (MEMS) device.

(5) FIG. 2b depicts the equivalent circuit of an electromechanical resonator.

(6) FIG. 3 has two graphs of simulations done for an antenna designed to operate at about 67.5 kHz in the LF band, the upper graph showing the inductance and quality factor of a suitably built electromechanical resonator (versus frequency) and the lower graph comparing the efficiency of the antenna versus the length of an active element thereof for both an embodiment utilizing the electromechanical resonator according to the upper graph with a similar antenna using a state of the art (SOA) conventional off the shelf (COTS) chip inductor (having a Q of 50).

(7) FIG. 4 has two graphs of simulations done for an antenna designed to operate at about 1.006 MHz in the MF band, the upper graph showing the inductance and quality factor of a suitably built electromechanical resonator (versus frequency) and the lower graph comparing the efficiency of the antenna versus the length of an active element thereof for both an embodiment utilizing the electromechanical resonator according to the upper graph with a similar antenna using a state of the art (SOA) conventional off the shelf (COTS) chip inductor (having a Q of 50).

(8) FIG. 5 has two graphs of simulations done for an antenna designed to operate at about 31.88 MHz in the VHF band, the upper graph showing the inductance and quality factor of a suitably built electromechanical resonator (versus frequency) and the lower graph comparing the efficiency of the antenna versus the length of an active element thereof for both an embodiment utilizing the electromechanical resonator according to the upper graph with a similar antenna using a state of the art (SOA) conventional off the shelf (COTS) chip inductor (having a Q of 50).

(9) FIG. 6 has two graphs of simulations done for an antenna designed to operate at about 2.005 GHz in the UHF band, the upper graph showing the inductance and quality factor of a suitably built electromechanical resonator (versus frequency) and the lower graph comparing the efficiency of the antenna versus the length of an active element thereof for both an embodiment utilizing the electromechanical resonator according to the upper graph with a similar antenna using a state of the art (SOA) conventional off the shelf (COTS) chip inductor (having a Q of 50).

(10) FIG. 7 shows a plot of the voltage gain for a 0.05 m monopole antenna matched with the MF quartz extensional mode resonator.

(11) FIGS. 8a and 8b depict embodiments where an electromechanical resonator is placed in an antenna element along the active element(s) of the antenna as opposed to at an input end of the antenna element.

(12) FIG. 9 is a graph showing that the efficiency of 12″ dipole antenna center loaded with a quartz shear mode resonator is better than the same antenna base loaded with a quartz shear mode resonator.

(13) FIGS. 10a and 10b depict embodiments where an electromechanical resonator is placed in an antenna element along the active element of the antenna and additionally at an input end of the antenna element.

(14) FIGS. 11a and 11b depict embodiments where an array of electromechanical resonators is placed in an antenna element along the active element(s) of the antenna instead of a single electromechanical resonator as in the embodiments of FIGS. 8a and 8b and FIG. 11c depicts an embodiment of an array of electromechanical resonators to be used with the embodiments of FIGS. 11a and 11b.

(15) FIGS. 12a and 12b depicts still additional embodiments where a single dipole or monopole antenna comprising thin metallic rods or metal sheets connected to a transmitter, receiver, or transceiver. In the case of the dipole antenna embodiment both thin metallic bodies are broken at multiple points along their length. In the case of the monopole antenna embodiment multiple breaks are placed somewhere along the length of the singular metallic body. Across the breaks one of the aforementioned electromechanical resonator types is placed.

(16) FIG. 13 depicts an embodiment of this invention wherein a central dipole or monopole antenna surrounded by multiple parasitic dipole or monopole antennas spaced <λ/4 away from the central element.

DETAILED DESCRIPTION

(17) The following description is presented to enable one of ordinary skill in the art to make and use the invention and to incorporate it in the context of particular applications. Various modifications, as well as a variety of uses in different applications will be readily apparent to those skilled in the art, and the general principles defined herein may be applied to a wide range of embodiments. Thus, the present invention is not intended to be limited to the embodiments presented, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

(18) In the following detailed description, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. However, it will be apparent to one skilled in the art that the present invention may be practiced without necessarily being limited to these specific details. In other instances, well-known structures and devices are shown in block diagram form, rather than in detail, in order to avoid obscuring the present invention.

(19) The reader's attention is directed to all papers and documents which are filed concurrently with this specification and which are open to public inspection with this specification, and the contents of all such papers and documents are incorporated herein by reference. All the features disclosed in this specification, (including any accompanying claims, abstract, and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example only of a generic series of equivalent or similar features.

(20) Furthermore, any element in a claim that does not explicitly state “means for” performing a specified function, or “step for” performing a specific function, is not to be interpreted as a “means” or “step” clause as specified in 35 U.S.C. Section 112(f). In particular, the use of “step of” or “act of” in the claims herein is not intended to invoke the provisions of 35 U.S.C. 112(f).

(21) This invention, in one embodiment thereof depicted by FIG. 1a, comprises an antenna 10. The particular antenna in this embodiment is a dipole antenna 10.sub.D of electrically small size, but the invention is not limited to dipole antennas. The dipole antenna has two thin metallic rods or metal sheets (often called arms) 12 which are connected, in use, to a transmitter, receiver, or transceiver 18. The arms 12 of the dipole antenna 10 of FIG. 1a are also known by those skilled in the art as active elements 12 of the antenna 10. Between the transmitter, receiver, or transceiver 18 and one of the two thin metallic rods or metal sheets or arms or active elements 12 is connected an electromechanical resonator 16 tuned to present a positive reactance at the intended frequency of operation of the antenna 10.sub.D. Since the antenna 10.sub.D is of electrically small size, it presents a negative reactance (that is it exhibits capacitance) at its intended frequency of operation. Ideally, the negative reactance of the antenna is at least partially offset by the positive reactance of the electromechanical resonator 16. Those schooled in this art realize that antennas used in practical applications often must function over a range of frequencies and also realize that RF signals transmitted by (or received by) the antenna have a bandwidth associated with them, so the term “the intended frequency of operation” in practice really refers to a range or band of frequencies at which the antenna 10 will be utilized. In the antenna art, one quality which relates to the suitability of an antenna for practical use is the Standing Wave Ratio (SWR). A SWR of one is ideal. That means all of the power sent by the transmitter 18 to the antenna 10.sub.D is being radiated by the antenna. A SWR of say 3.0 is often unacceptable. Placing the electromechanical resonator 16 in series with the antenna will improve the SWR of the antenna/resonator combination compared to the antenna 10D alone without the electromechanical resonator 16.

(22) The electromechanical resonator 16 can either be embodied with one of the antenna elements or it may be an added component. When the antenna is intended to be connected to a transmitter or transceiver, an antenna junction is provided which often called an antenna feed point and the two thin metallic rods or metal sheets are often called driven elements. The feed point may be considered to be either upstream or downstream of the electromechanical resonator 16 of FIG. 1a depending on, for example, whether the electromechanical resonator 16 is embodied with the antenna 10 or provided as an add-on element.

(23) The transmitter, receiver, or transceiver 18 may be remotely located relative to the antenna in which case a transmission line 17, which may be many feet in length, connects the transmitter, receiver, or transceiver 18 to the antenna 10.sub.D. On the other hand the transmitter, receiver, or transceiver 18 may be located very close to the antenna 10.sub.D if the transmitter, receiver, or transceiver 18 is embodied as a hand held communication apparatus. In such an embodiment, the transmission line 17 may be very short (and thus effectively omitted) and may be embodied mostly as conductive traces on a printed circuit board disposed within the aforementioned hand held communication apparatus.

(24) FIG. 1b depicts another embodiment of an electrically small dipole antenna 10.sub.D2 that is similar to the embodiment of FIG. 1a, but in this embodiment an electromechanical resonator 16 is placed in series with each of the two active elements 12 of a dipole antenna and a feed line (if present, see FIG. 1a) and the transmitter, receiver, or transceiver 18.

(25) In an another alternative embodiment depicted by FIG. 1c, the antenna 10 comprises a monopole antenna 10.sub.M having of a singular metallic rod or metal sheet or active element 12 disposed over a ground plane 14 and typically mounted in a direction normal to the ground plane 14. An antenna feed point occurs between (i) the monopole where it approaches, but often does not contact, the ground plane and (ii) the ground plane. Connected across the terminals of the aforementioned monopole antenna is a transmitter, receiver, or transceiver 18 connected in series with an electromechanical resonator 16 tuned to present a positive reactance at the intended frequency of operation for the antenna 10. The ground plane 16 can be earthen ground (i.e. the earth's surface . . . perhaps augmented with ground radials . . . or it may be a metallic surface(s) such as can be found on equipment and/or vehicles of many different types, including, but not limited to cars, trucks, recreational vehicles, ships, boats, submarines, satellites, and military equipment.

(26) In these embodiments, the tuning of the electromechanical resonator 16 to present a positive reactance at the intended frequency of operation of the antenna 10 is achieved either by modifying the construction or geometry of the resonator 16 before installation into or adjacent the antenna 10 or by using external capacitive tuning elements to shift its resonant frequency. FIG. 2a shows the electromechanical resonator 16 being embodied as a quartz shear mode MEMS (Micro Electro-Mechanical System) device made by HRL Laboratories LLC of Malibu, Calif. Other possible embodiments of the electromechanical resonator 16 are discussed below.

(27) The embodiments of FIGS. 1a-1c show the use of the present invention with simple antennas: dipoles and monopoles. The invention, however, may be used with other antenna types, such as: slot antennas, Vivaldi antennas, Yagi-Uda antenna, etc. The present invention is particularly useful when the antenna is electrically short. When an antenna is electrically short it exhibits capacitive reactance (the value of its reactance is negative according to how reactance is conventionally measured). Those skilled in the art recognize if an antenna is reactive that causes an impedance mismatch between the antenna and the transmitter, receiver, or transceiver 18 to which it is connected. A small amount of impedance mismatch can normally be tolerated by the transmitter, receiver, or transceiver 18 to which the antenna is connected without difficulty. But a large mismatch (resulting in a VSWR is greater than 2.0 to 4.0 for example) can result in a receiver functioning much less efficiently or in a transmitter shutting itself down as a mean of self protection from the power reflected by the antenna 10 in an impedance mismatch situation.

(28) For hand held transceivers the size of the antenna can be much bigger than the size of the electronics in the transceiver itself. So reducing the size of the antenna has many advantages for the user in terms of user convenience, if nothing else, but reducing the size of the antenna will cause the antenna to exhibit capacitive reactance and hence an impedance mismatch if step are taken to deal with that capacitive reactance.

(29) In the following discussions, an ideal situation will be discussed where in reactance of the antenna is “cancelled” or “offset” by the electromechanical resonator(s) 16. But in real life, the electromechanical resonator(s) 16 may present (a) not quite enough positive reactance (inductive reactance) to completely offset the negative reactance (capacitive reactance) of the antenna or present (b) perhaps a little more positive reactance (inductive reactance) than needed to offset the negative reactance (capacitive reactance) of the antenna. But so long as the resulting impedance mismatch resulting from situations (a) or (b) above can be tolerated by the transceiver 18, then the total reactance of the antenna 10 plus the electromechanical resonator(s) 16 has been reduced to an acceptable level, even if not completely cancelled.

(30) In mathematical terms it is easier to talk about the ideal situation of cancelling the reactance of an electrically short antenna, but it should be borne in mind, that getting close to cancellation (so that the VSWR is reduced to an acceptable level) is a highly desirable result of utilizing the present invention.

(31) TABLE-US-00001 TABLE I Frequency Bands UHF band and above VHF & UHF band MF and HF bands VLF and LF bands Electromechanical UHF BAW Resonator VHF Shear Mode MF Extensional LF Tuning Fork Resonator [Source: R. Ruby, “11E−2 Resonator [Source: Mode Resonator Resonator [Source: type and Review and comparison Multiphysics simulation [Source: CX4 Multiphysics data sources of bulk acoustic wave performed at HRL Crystal Data Sheet, simulation FBAR, SMR Technology.” Laboratories] Statek Corporation.] performed at HRL Ultrasonics Symposium, Laboratories] 2007. IEEE. IEEE, 2007.] R.sub.1 (Ω) 0.26 3 400 125 C.sub.1 (F) 9.14E−14 5.00E−15 2.00E−15 1.99E−13 L.sub.1 (H) 7.10E−08 5.00E−03  12.665  31 C.sub.0 (F) 1.56E−12 8.00E−13 8.00E−13 7.60E−13

(32) The electrical properties of a electromechanical resonator 16 can be modeled as a series inductor L.sub.1, capacitor C.sub.1, and resistor R.sub.1, in parallel with another capacitor C.sub.0. This equivalent circuit 19 (see FIG. 2b), also known as the Butterworth-Van Dyke (BVD) model, has both a series and parallel resonance. Exemplary BVD parameter values are listed in table I above along with a suggested electromechanical resonator type to be used in the frequency bands identified in that table. At frequencies between the series and parallel resonance frequencies, the reactance of this circuit of FIG. 2b is positive causing the electromechanical resonator to effectively behave like an inductor over a narrow frequency range (<1% bandwidth). Because the resistance associated with this reactance is much lower than a comparable prior art coiled inductor, the effective inductor Q is much higher than a comparable prior art coiled inductor. When placed in series with the aforementioned dipole or monopole antenna 10, this high Q inductance serves to improve efficiency by canceling the capacitive reactance of the electrically short antenna 10 and improving impedance matching to transmitter, receiver, or transceiver modules 16. The electromechanical resonator 16 used in these embodiments is selected such at its BVD parameter values place the aforementioned series and parallel resonance values on either side of the intended frequency of operation of the antenna and its transmitter, receiver, or transceiver 18.

(33) According to R. C. Hansen (see R. C. Hansen, “Efficiency and Matching Tradeoffs for Inductively Loaded Short Antennas” IEEE Transactions on Communications, Vol. Com-23, No. 4, April 1975), the radiation efficiency of an electrically small dipole or monopole antenna is given by equation 1 (Eqn. 1) below:

(34) $\begin{array}{cc}\eta =\frac{R_{\mathrm{rad}}}{R_{\mathrm{rad}}+R_{\mathrm{loss}}+R_{\mathrm{match}}}& \left(\mathrm{Eqn}.1\right)\end{array}$

(35) where R.sub.rad is the antenna radiation resistance for a monopole antenna, R.sub.loss is the ohmic loss of the antenna, and R.sub.match is the ohmic loss associated with the matching network. For monopole antennas, R.sub.rad=10k.sup.2h.sup.2 where k is the freespace wavenumber and h is the height of the monopole, R.sub.loss=R.sub.sh/3ra where a is the diameter of the conductor and R.sub.s is the surface resistivity in ohms per square, and R.sub.match=|X.sub.a|/Q where X.sub.a is the antenna reactance and Q is the quality factor of the inductor used to match the antenna reactance. Traditional matching networks employing coiled inductors with low Q (˜50) result in large ohmic losses and poor efficiency for electrically small antennas. Furthermore, as antennas become excessively small (and thus exhibits a high negative reactance) extremely large coiled inductors have been required to generate the reactances required for effective matching. This invention overcomes these limitations by replacing coiled inductors used in the prior art with high Q electromechanical resonators 16.

(36) The selection of particular type of electromechanical resonator 16 preferably used depends primarily on the frequency band of operation. At VLF and LF bands tuning fork resonators are preferably utilized, while at MF and HF bands extensional mode resonators are preferably utilized, at VHF and UHF frequencies shear mode resonators are preferably utilized and at L- to C-band frequencies Bulk Acoustic Wave resonators are preferably utilized. Each of these resonators 16 employs a piezoelectric crystal for coupling applied of voltages to mechanical modes. In the preferred embodiments this crystal is quartz, although any variety of piezoelectric crystal can be utilized including MN and LiNbO.sub.3. The choice of crystal is governed by the desired temperature stability, resonator Q, nonlinear characteristics under high drive levels, as well as the piezoelectric effective coupling coefficient k.sub.eff.sup.2.

(37) It should also be recognized that the resonator type suggested in the preceding paragraph and in Table I just suggestions as other electromechanical resonator types may be used instead, particularly when the desired frequency of operation at near a band edge as identified in the table. For example, the BVD model parameters for a 32 KHz extensional mode quartz resonator (instead of the suggested shear mode resonator) are listed in Table II below:

(38) TABLE-US-00002 TABLE II Parameter Value C.sub.0 2 pF C.sub.1 10 fF L.sub.1 2474 H R.sub.1 248 Ω

(39) The antenna specification will include such items as resonant frequency, bandwidth, voltage out for a given input AC magnetic field, and output impedance. Once these specifications are determined the resonator design can be determined. For UHF operation, a shear mode resonator will be the likely be the superior choice as noted above. For HF operation, an extensional mode resonator would be best choice to keep the thickness of the resonator from becoming excessively large to prevent the use of deep trench quartz etching. For LF applications, a tuning fork design will probably be the best choice, again due to thickness issues for an optimized design.

(40) Now, to demonstrate the effectiveness of matching electrically small dipole antennas 10.sub.D and electrically small monopole antennas 10.sub.M with electromechanical resonators 16, simulations with various resonator types were performed at different frequency bands or ranges. Van-Dyke parameters for a quartz tuning fork at LF frequencies (30 kHz to 300 kHz) and a quartz shear mode resonator at VHF frequencies (30 MHz to 300 MHz) were obtained using multi-physics simulations performed using COMSOL simulation software. Van-Dyke parameters for a quartz extensional mode resonator at MF frequencies (300 kHz to 3 MHz) and an AlN BAW resonator at S-band frequencies (2 to 4 GHz) were obtained from published measurements as noted in Table I. Using these Van-Dyke parameters, the effective inductance (L.sub.eff=X.sub.VanDyke/ω) and inductor Q (Q.sub.eff=X.sub.VanDyke/R.sub.VanDyke) were calculated and used to determine the predicted efficiency for electrically small monopole antennas in the respective frequency range. FIGS. 3-6 compare this efficiency with the same antennas matched with a traditional prior art chip coil inductor of Q=50.

(41) FIG. 3 has two graphs of simulations done for an antenna designed to operate at about 67.5 kHz in the LF band using the resonator having BVD parameters listed in the fourth containing data column (e.g., the right most column) in Table I. FIG. 4 also has two graphs of simulations done for an antenna designed to operate at about 1.006 MHz in the MF band, the resonator having BVD parameters listed in the third column containing data in Table I. FIG. 5 has also two graphs of simulations done for an antenna designed to operate at about 31.88 MHz in the VHF band, the resonator having BVD parameters listed in the second column containing data in Table I. Finally, FIG. 6 has two graphs of simulations done for an antenna designed to operate at about 2.005 GHz in the UHF band, the resonator having BVD parameters listed in the first column containing data in Table I above.

(42) For a given resonator design, the optimal operating point in frequency occurs when the effective inductor Q is maximum. The generated inductance value at this optimum, can be modified by changing the shape and size of the resonator to match the capacitive reactance of the antenna. In general, the higher the modal mass of the mechanical resonator, the larger the equivalent inductance. One potential limitation of this technique, is that the bandwidth over which this high Q inductance can be achieved is exceedingly narrow.

(43) Modal mass is the mass of a spring/mass resonator that is electrically equivalent to the BVD model of the resonator. Thus, high L1 is equivalent to high modal mass. The modal mass is only weakly determined by the modal confinement and hence the Q. One can easily vary the Q for a particular resonator by varying the electrode and plate geometry. However, for changing the modal mass one needs to change the size of the resonator which usually produces a different optimized operating frequency.

(44) While each of the FIGS. 3-5 show marked improvements in efficiency if an electromechanical resonator 16 is used rather than a prior art chip inductor, consider the marked improvement for the antenna represented by FIG. 5. This antenna is resonant at 31.88 MHz. Those skilled in the art would immediately recognize that a full size (quarter wavelength) monopole antenna resonant at 31.99 MHz would have a height of about 2.5 m. Of course, that dimension can be calculated exactly, but what is of interest is an electrically short antenna. A monopole having a height of only 1 m is very clearly electrically short if it is to be operated at 31.88 MHz. If an electromechanical resonator 16 is used (as depicted by FIG. 1b) having the characteristics of the upper graph of FIG. 5, as can then be seen from the lower graph, the efficiency of the resulting antenna is about 95% (see point “A” marked on the lower graph). But if a prior art chip inductor is instead used (having a Q of only about 50), then the efficiency drops to about 30% (see point “B” marked on the lower graph). The advantage of using an electromechanical resonator 16 with a Q of abut 500 (see point “C” marked on the upper graph) instead of a prior art chip inductor in the monopole antenna 10 of FIG. 1b is nothing less than remarkable.

(45) It appears that the higher the Q of the electromechanical resonator 16 the greater the improvement in efficiency. Compare FIGS. 3-6. The BAW electromechanical resonator of FIG. 6 has a Q between 50 and 100 and shows little improvement efficiency-wise over a chip inductor (with an assumed Q of 50). But using a BAW electromechanical resonator instead of a chip inductor can still yield benefits since the BAW electromechanical resonator should be smaller in size and also the BAW electromechanical resonator should have series and parallel resonances (and hence exhibit 2 poles), and this present a better match than would a single pole chip inductor.

(46) FIG. 7, shows a plot of the voltage gain for a 0.05 m monopole antenna matched with the MF quartz extensional mode resonator. The efficiency is shown in FIG. 4. It can be seen from this plot the 3-dB bandwidth of this voltage transfer is less than 10 Hz.

(47) In another embodiment this invention comprises a dipole antenna (see FIG. 8a) or monopole (see FIG. 8b) antenna 10 comprising two thin metallic rods or metal sheets (arms) connected to a transmitter, receiver, or transceiver 18. In the case of the dipole antenna both thin metallic bodies (arms) are formed to define two portions 12.sub.1 and 12.sub.2 which are separated from each at some point along their length (preferably at a point about 40% of the total length of arm from the driven end). In the case of the monopole antenna a single break or opening in placed somewhere along the length of the singular metallic body in that embodiment. Connected across the break or opening is one (or more) of the aforementioned electromechanical resonators 16. This resonator 16 is once again tuned to present a positive reactance to cancel (or partially offset) the capacitive reactance of the dipole or monopole antenna. In addition to mathematically canceling the reactive impedance of the antenna, placement of the resonator into the body of the dipole or monopole serves to increase the radiation resistance of the antenna by redistributing current on the antenna structure. This effect is captured by the following modified radiation efficiency equation provided by R. C. Hansen along its body can be written as:

(48) $\begin{array}{cc}\eta =\frac{Q_L\beta R_r}{Q_L\beta R_z+\alpha X_a}& \left(\mathrm{Eqn}.2\right)\end{array}$

(49) where Q.sub.L, is the quality factor of the loading inductor, β and α are constants defined by Hansen, R.sub.r is the radiation resistance of the antenna unloaded, and X.sub.a is the reactance of the antenna unloaded.

(50) To demonstrate the effect of loading electromechanical resonators into an electrically small dipole antenna, simulations of a 32 MHz sheer mode resonator were performed in COMSOL simulation software. The parameters of the BVD model extracted from this simulation are given in Table III below (and these parameters are also listed for a VHF device in Table I above):

(51) TABLE-US-00003 TABLE III Parameter Value C.sub.0 0.8 pF C.sub.1 5 fF L.sub.1 5 mH R.sub.1 3 Ω

(52) Around 31.9 MHz this resonator exhibits an inductance of 31.5 μH along with a large quality factor of 520. See FIG. 9 which shows that the efficiency of 12″ dipole antenna center loaded with a quartz shear mode resonator vs. the same antenna base loaded with a quartz shear mode resonator.

(53) In additional embodiments this invention (see FIGS. 10a and 10b) a dipole antenna 10.sub.D or monopole antenna 10.sub.M comprises one or more thin metallic rods or metal sheets or bodies 12 connected to a transmitter, receiver, or transceiver 18. In the embodiment of FIG. 10a a dipole antenna both thin metallic bodies 12 are separated at some point along their length to define two portions 12.sub.1 and 12.sub.2 with an opening therebetween. In the embodiment of FIG. 10b, a monopole antenna 10M has a single break or opening in its thin metallic rod, metal sheet or body, forming or defining two portions 12.sub.1 and 12.sub.2, the opening occurring somewhere along the length of the metallic body (preferably about 40% along the length). Across these breaks or openings, one of the aforementioned electromechanical resonators 16 (numbered 16-2 and 16-3 in the embodiment of FIG. 10a) is placed. The resonator(s) is(are) tuned to present a positive reactance to partially cancel the capacitive reactance of the dipole or monopole antennas 10.sub.D, 10.sub.M. The remaining reactance may be cancelled (or further offset) by an additional electromechanical resonator 16-1 placed in series with the antenna 10.sub.D, 10.sub.M at its feed point. In this configuration some (but preferably not all) of the electromechanical resonators 16, 16-1, 16-2 and 16-3 can be replaced with conventional inductors.

(54) In yet other embodiments of this invention (see FIGS. 11a and 11b) a single dipole antenna or a monopole antenna may have its thin metallic rod(s) or metal sheet(s) connected to a transmitter, receiver, or transceiver 18. In the case of the embodiment of FIG. 11a both thin metallic bodies 12 are broken at some point along their length. In the case of the embodiment of FIG. 11b, a single break or opening in placed somewhere along the length of the singular metallic body 12. Across the break(s) or opening(s) in elements 12 are placed multiple electromechanical resonators 16 arranged preferably as an array 16.sub.array of resonators 16. The resonators 16 in array 16.sub.array are all tuned to present a positive reactance to cancel (or partially reduce) the capacitive reactance of the dipole or monopole antenna 10.sub.D, 10.sub.M. These resonators are preferably configured in a network or as an array having an equal numbers of individual series and parallel connected resonators 16 connected in an array 16.sub.array such as that shown by FIG. 11c. The array 16.sub.array is connected across each aforementioned break(s) or opening(s). This network or array configuration serves to reduce the voltage and current seen across each resonator 16 while maintaining the same reactance value as if a single resonator were used in lieu of array 16.sub.array.

(55) In additional embodiments of this invention (see FIGS. 12a and 12b) a single dipole or monopole antenna comprising two thin metallic arms or metal sheets connected to a transmitter, receiver, or transceiver 18. In the case of the dipole antenna both thin metallic bodies are broken or separated at multiple points along their length thereby defining portions 12.sub.1, 12.sub.2, 12.sub.3, and 12.sub.4 of each arm 12. In the case of a monopole antenna embodiment (see FIG. 12b), multiple breaks or openings are occur somewhere along the length of the singular metallic body. Connected across each of the breaks or openings is one (or an array—which may be a two dimensional array) of one (or more) of the aforementioned types of electromechanical resonators 16. These resonators 16 are all tuned to present a positive reactance to cancel (or at least partially offset) the capacitive reactance of the dipole or monopole antenna 10. The reactance value which need to be presented by each of these resonators 16 at the intended frequency of operation for the antenna is preferably determined by full wave simulation and occurs —. This embodiment serves to reduce the voltage seen across each resonator 16 compared to those embodiments having a single resonator in an arm of a dipole or monopole antenna.

(56) In a final embodiment of this invention comprises a central dipole or monopole antenna surrounded by multiple parasitic dipole or monopole antennas spaced <λ/4 away from the central element (see FIG. 13). In the case of the dipole array both the central antenna element and the parasitic elements are comprised of two thin metallic rods or metal sheets. In the case of the monopole array both the central antenna element and the parasitic elements are comprised of a single metallic rod or metal sheet placed over a ground plane. In both the dipole and monopole configurations, the central element is connected to a transmitter, receiver, or transceiver 18, whereas the surrounding parasitic dipoles are connected to some load value Z.sub.L which can be tuned using known methods to form directive beams in the radiation pattern of the array. Each element is broken at one or multiple locations along their length. Electromechanical resonators 16 tuned to present a positive reactance are placed across each break to cancel the negative reactance of the antenna as well as to alter the current distribution on the antenna.

(57) The antenna elements are often described as being “thin”. Thinness can be a desirable attribute if the antenna element telescopes, for example, so that it can be pulled out of a hand held communication apparatus in a telescoping manner. The same is true for the diameter of the antenna element. Telescoping antenna elements for hand held communication apparatus are often only around ¼ inch in diameter. But antenna elements which are thicker and/or have a larger diameter can be superior from a purely electrical performance perspective and/or from a mechanical suitability perspective. So in the context of the present invention, there is no need for the antenna elements to be thin or thick walled or of a small or large diameter. The antenna elements, as a practical matter, are preferably of circular cross section, but they can be of any suitable cross section. The antenna elements, as a practical matter, are made of metal.

(58) This concludes the description of embodiments of the present invention. The foregoing description of these embodiments and the methods of making same has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form or methods disclosed. Many modifications and variations are possible in light of the above teachings. It is intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto.