This invention relates to structures and methods formed from high temperature superconductors. More particularly, it relates to devices such as resonators having high Q and reduced intermodulation distortion for use as passive microwave devices.
Electrical components come in various conventional forms, such as inductors, capacitors and resistors. A lumped electrical element is one whose physical size is substantially less than the wave length of the electromagnetic field passing through the element. A distributed element is one whose size is larger than that for a lumped element. As an example, a lumped element in the form of an inductor would have a physical size which is a relatively small fraction of the wave length used with the circuit, typically less than ⅛ of the wavelength.
Inductors, capacitors and resistors have been grouped together into useful circuits. Useful circuits including those elements include resonant circuits and filters. One particular application has been the formation of filters useful in the microwave range, such as above 500 MHZ.
Considering the case of conventional microwave filters, there have been basically three types. First, lumped element filters have used separately fabricated air wound inductors and parallel plate capacitors, wired together into a filter circuit. These conventional components are relatively small compared to the wave length, and accordingly, make for a fairly compact filters. However, the use of separate elements has proved to be difficult in manufacture, and resulting in large circuit to circuit differences. The second conventional filter structure utilizes mechanical distributed element components. Coupled bars or rods are used to form transmission line networks which are arranged as a filter circuit. Ordinarily, the length of the bars or rods is ¼ or ½ of the wave length at the center frequency of the filter. Accordingly, the bars or rods can become quite sizeable, often being several inches long, resulting in filters over a foot in length. Third, printed distributed element filters have been used. Generally they comprise a single layer of metal traces printed on an insulating substrate, with a ground plane on the back of the substrate. The traces are arranged as transmission line networks to make a filter. Again, the size of these filters can become quite large. The structures also suffer from various responses at multiples of the center frequency.
Various thin-filmed lumped element structures have been proposed. Swanson U.S. Pat. No. 4,881,050, issued Nov. 14, 1989, discloses a thin-film microwave filter utilizing lumped elements. In particular, a capacitor π network utilizing spiral inductors and capacitors is disclosed. Generally, a multi-layer structure is utilized, a dielectric substrate having a ground plane on one side of the substrate and multiple thin-filmed metal layers and insulators on the other side. Filters are formed by configuring the metal and insulation layers to form capacitive π-networks and spiral inductors. Swanson U.S. Pat. No. 5,175,518 entitled “Wide Percentage Band With Microwave Filter Network and Method of Manufacturing Same” discloses a lumped element thin-film based structure. Specifically, an alumina substrate has a ground plane on one side and multiple layer plate-like structures on the other side. A silicon nitride dielectric layer is deposited over the first plate on the substrate, and a second and third capacitor plates are deposited on the dielectric over the first plate.
Historically, such lumped element circuits were fabricated using normal, that is, non-superconducting materials. These materials have an inherent loss, and as a result, the circuits have various degree of lossiness. For resonant circuits, the loss is particularly critical. The quality factor Q of a device is a measure of its power dissipation or lossiness. Resonant circuits fabricated from normal metals have Q's at best on the order of a few hundred.
With the discovery of high temperature superconductivity in 1986, attempts have been made to fabricate electrical devices from these materials. The microwave properties of the high temperature superconductors has improved substantially since their discovery. Epitaxial superconductive thin films are now routinely formed and commercially available. See, e.g., R. B. Hammond, et al., “Epitaxial Tl2Ca1Ba2Cu2O8 Thin Films With Low 9.6 GHz Surface Resistance at High Power and Above 77 K”, Appl. Phy. Lett., Vol. 57, pp. 825–827, 1990. Various filter structures and resonators have been formed. Other discrete circuits for filters in the microwave region have been described. See, e.g., S. H. Talisa, et al., “Low- and High-Temperature Superconducting Microwave Filters,” IEEE Transactions on Microwave Theory and Techniques, Vol. 39, No. 9, September 1991, pp. 1448–1554.
The need for compact, reliable narrow band filters has never been stronger. Applications in the telecommunication fields are of particular importance. As more users desire to use the microwave band, the use of narrow band filters will increase the number of users in the spectrum. The area from 800 to 2,000 MHZ is of particular interest. In the United States, the 800 to 900 MHz range is used for analog cellular communications. The personal communications services are planned for the 1,800 to 2,000 MHZ range.
Many passive microwave devices, for example, resonators, filters, antennas, delay lines and inductors, have been fabricated in planar form utilizing high temperature superconducting thin films. As described, such structures are often smaller than conventional technologies in terms of physical size. However, these devices are also limited in their size given the constraints of fabricating high quality, epitaxial films. As a result, devices fabricated in HTS films are often of a quasi-lumped element nature, that is, where the nominal size the device is smaller than the wavelength of operation. This often results in folding of devices, which leads to significant coupling between lines.
Despite the clear desirability of improved electrical circuits, including the known desirability of converting circuitry to include superconducting elements, efforts to date have been less than satisfactory in all regards. It has proved to be especially difficult in substituting high temperature superconducting materials to form circuits without severely degrading the intrinsic Q of the superconducting film. These problems include circuit structure, radiative loss and tuning and have remained in spite of the clear desirability of an improved circuit.
This patent relates to various novel structures and methods for forming high temperature superconducting devices, most particularly resonators. These devices have high Q, that is, at least in excess of 1,000, more preferably in excess of 25,000, and most preferably in excess of 50,000. Generally, these inventive structures reduce peak current densities relative to known structures. One significant result of reduced current density is in reduced intermodulation effects. In one embodiment, a snake resonator includes a plurality of long runs, connected by a plurality of turns, wherein certain ones of the long runs are wider than certain other ones of the long runs the wider runs being those that would have a higher current density if all runs were of equal width.
In one aspect of this invention, a spiral snake resonator having a terminal end disposed within the resonator is provided. In the preferred mode of this embodiment, multiple long runs are connected by turns, where the turns at one end of the resonator are concentric semicircles, with the center of radius being disposed between long runs. The turns at the second ends of the resonator are also concentric semicircles, though with the center of curvature being disposed at the end of a centrally disposed long run.
In one specific preferred embodiment, a spiral snake resonator includes a plurality of N long runs, each one of the plurality of N long runs having two ends and a plurality of turns connecting the plurality of N long runs to each other in a spiral snake configuration. The resonator is characterized in that one end of a first long run of the plurality of N long runs is connected to one end of a second long run of the plurality of N long runs by a first turn of the plurality of turns of a first handedness, and the other end of the second long run is connected to one end of a third long run of the plurality of N long runs by a second turn of the plurality of turns of said first handedness, the third long run being disposed between the first long run and the second long run, the remaining long runs of the plurality of N long runs being by repeating the connections of the first, second and third long run for the remaining plurality of N long runs using the remaining plurality of turns starting at the other end of the third long run and terminating at one end of the Nth long run of the plurality of N long runs. The resonator is further characterized by the feature that the plurality of turns located at the first ends of the plurality of long runs are concentric with each other around a center point disposed between long runs N and N−1 and wherein the plurality of turns located at the second ends of the plurality of long runs are concentric with each other around a center point disposed on the end of the Nth long run.
Accordingly, it is an object of this invention to provide improved high temperature superconducting structures.
It is yet a further object of this invention to provide improved resonators having reduced intermodulation.
It is yet a further object of this invention to provide resonators having reduced peak current densities.
It is yet a further object of this invention to provide high Q, superconducting resonators having reduced intermodulation effects.
a is a plan view of a zig-zag or serpentine resonator at its first harmonic and
a, 18b, 18c and 18d show outputs of electromagnetic model simulations for the magnitude in the fundamental mode (
a, 19b, 19c and 19d show current density cross sections for a zig-zag, spiral in, spiral out, spiral and ALF spiral in, spiral out resonators using a planar 3D electromagnetic simulations package developed by US company Sonnet, Inc.
a shows a graph of the unloaded Q (QU) as a function of gap width.
b shows a graph of the intermodulation power PIMD as a function of gap width.
a and 23b show graphs of the current in the hairpin resonator of
a illustrates a spiral in, spiral out resonator according to one embodiment of the invention.
b and 25c show results of operation of a resonator of this invention.
The input pads 10 and output pad 16 serve to increase the equivalent capacitance to ground relative to a structure having no or smaller input and output pads. Preferably, the amount of equivalent capacitance to ground is selected in accordance with the electrical requirements of the circuit. As shown in
The center frequency fc of such a resonator is
fc∝1/√{square root over (LC)}
wherein L is the inductance and C is the capacitance of the resonator. A condition of resonance is that the energy stored in the magnetic field W1 and the energy stored in the electric field Wc must be equal to:
wherein V is the voltage and I is the current, and W is the energy stored at resonance.
When the unloaded Q is much larger than the loaded Q, as is often the case for superconducting filters, then the stored energy at resonance, W, is determined by the loaded Q. Thus, if the frequency and loaded Q are fixed, it is clear that in order to decrease the circulating current we must increase L, while simultaneously decreasing C to preserve the resonant frequency.
To a first approximation, the unloaded Q of an HTS resonator is Q=wL/Rs where w is the resonant frequency and Rs is the surface resistance at that frequency. Thus, we see an additional advantage of these resonators over their QLE counterparts in terms of their higher unloaded Qs.
Using these structures, small area resonators can reliably be constructed which have the following desirable properties.
The spiral in, spiral out structure of
Broadly, the technique disclosed herein is for increasing the line width of a folded HTS resonator as a function of current density. Considering a structure such as
Ideally, the structure of the graduated resonators would be smooth lines, such as shown in the smooth lines of
Preferably, the ratio of widths from outside of long runs 120 at the ends of the resonator to adjacent segments is 1:3. However, under certain circumstances, this can create an impedance mismatch which becomes significant, and for practical size requirements utilizing current processing technology makes the width of the long runs too small or fine.
Alternatively, the circuit may be modified in other ways. For example, if the circuit were split into three segments, as opposed to the nine segments described previously, the values would be approximately as follows:
b shows a zig-zag or snake resonator operable at a first harmonic, where
a and 18b show the magnitude and phase, respectively, on a modeled system of a spiral in, spiral out resonator. The modeled structure is based upon a resonator of the structure shown in
c and 18d show the magnitude and phase respectively for the simulation of the same spiral in, spiral out resonator but at the first harmonic. The magnitude shows that the magnitude rises from the ends of the resonator to two peaks situation roughly at ¼ and ¾ of the length of the line, with the magnitude decreasing from the peaks to the center of the resonator. The phase shown in
It has been discovered that the use of a symmetric mode, that is, one in which currents flow in the same direction in adjacent legs of the resonator, such as is shown in
Experimental Results
The following table provides data regarding spiral resonators, and spiral in, spiral out snake resonators of the size and area identified.
a, 19b, 19c, 19d show Sonnet current density cross-sections for zig-zag, spiral in, spiral out, spiral and higher mode (ALF) spiral in, spiral out resonators. Specifically,
The response of the band reject resonator may be characterized in terms of three quantities, the resonance frequency, F0, and the loaded and unloaded quality factors, QL and QU, respectively. F0 and QL are determined by the geometry of the resonator 160 and substrate.
For the actual experiments performed, the width of the runs 162, 164 was fixed at 0.4 mm, with L, G and S being adjustable parameters. The resonance frequency of 7.4 GHz was chosen.
a shows a graph of the unloaded quality factor (Qu) of the gap g for a series of hairpin resonators. The experimental results for the symmetric resonators (second mode, represented by circles), the antisymmetric resonators (first mode, represented by squares) and the straight resonator (represented by triangles) are compared with numerical calculations (solid, long-dashed, and short-dashed line, respectively). The dotted line accounts for the losses in the lid for the symmetric resonators.
b shows a graph of the intermodulation power PIMD measured in decibels as a function of gap g for a series of hairpin resonators. The experimental results for the symmetric resonators (second mode, represented by circles), the antisymmetric resonators (first mode, represented by squares) and the straight resonator (represented by triangles) are compared with numerical calculations (solid, long-dashed, and short-dashed line, respectively). The open symbols represent the raw data as measured before correction to {tilde over (Q)}=1700. The intermodulation power is measured in decibels referenced to 1 mW.
a shows a graph of the current in the hairpin resonator of
Four sets of resonators were designed:
The circuits were clipped into gold plated test fixtures using Indium foil below the circuit to ensure proper thermal and electrical contact. The microwave circuit was then completed by wire bonds at both ends of the 50 Ω thru line. Note that the electrical ground plane seen by the resonator is, for the most part, provided by the unpatterned film on the back side of the substrate.
The microwave transmission characteristics, S21, were measured using HP 8720B Vector Network Analyzer in order to determine f0, QU and QL which characterize the linear response of the circuit at low microwave powers. The Qs are obtained from direct measurements of the fractional bandwidths at −3 dB, Δf−2 dB, the insertion loss, S21(f0), and the width of the resonance 3 dB above the minimum, Δf+3 dB. In all cases the input power to the resonators was held fixed in PIN=−20 dBm.
The measured and calculated Qs are presented in
For the antisymmetric resonators the calculations are in good agreement with the measurements. For smaller gap sizes QU is degraded. This can be understood from the antiparallel currents running in the gap region. Therefore, high current densities have to flow at the inner edges of the legs to screen out this field from the superconducting films. These high current densities lead to increased losses and to higher intermodulations. In contrast, for the symmetric mode the parallel currents lead to fields that cancel within the gap and no such degradation is expected. For this mode we find almost exactly double what is measured (the dotted line shows half of the calculated values), using the same surface impedances used to evaluate the anti-symmetric mode Qs.
The circuits were tested with and without an Aluminum lid placed 0.150 inches above the circuit. For the first set of resonators the effect of removing the lid was only a slight shift in the resonant frequency with no detectable change in QU or QL. For the resonators which made use of the first harmonic (sets 2 and 3), the effect was far more severe; there QU dropped close to an order of magnitude as the lid was removed. This is an indication that the microwave fields associated with the resonator are far more extended for the symmetric modes than for the anti-symmetric ones.
The two microwave signals required to produce intermodulation products were symmetrically placed 15 kHz above and below f0, for a signal separation of 30 kHz. Continuous Wave (CW) Signals were produced using HP 8341B and HP 83640A synthesized sweepers, and the signals detected using a Tektronix 3784 Spectrum Analyzer. The output power of the two sources was measured using an HP 437B power meter, and adjusted so that the two signals arrived at the sample with the same magnitude.
The absolute magnitude of third order intermodulation products. PIMD, as a function of input power provided to the device, PIN was measured. For the 30 kHz signal separation we are using here these signals are generated at f0±45 kHz. As can be seen in
PIMD at a fixed input power of PIN+−20 dBm is presented as a function of gap width for the first two sets of resonators and the straight one in
a shows a spiral in, spiral out snake resonator. When realized with YBCO films deposited on 0.015″ thick MgO substrates the resonator was 5.2 mm by 10.4 mm in area. The average unloaded quality factor of these resonators was measured to be 110,000 at a resonance frequency 845 MHz and a temperature of 77K.
b shows the measured frequency response of the S-parameters for a quasi elliptic band reject filter realized using six of the resonators in
c shows a simulation of the filter in 25b taking the average measured unloaded quality factor into account. The unloaded quality factor is apparent in the depth of the nulls as well as the sharpness in the corners of the filter.
Although the foregoing invention has been described in some detail by way of illustration and example for purposes of clarity and understanding, it may be readily apparent to those of ordinary skill in the art in light of the teachings of this invention that certain changes and modifications may be made thereto without departing from the spirit or scope of the appended claims.
This application is a continuation of application Ser. No. 10/167,938, filed Jun. 10, 2002, now issued as U.S. Pat. No. 6,895,262 which is a continuation of application Ser. No. 09/460,274, filed Dec. 13, 1999, now issued as U.S. Pat. No. 6,424,846, which is a continuation of application Ser. No. 08/885,473, filed on Jun. 30, 1997, issued as U.S. Pat. No. 6,026,311, which is a continuation-in-part of application Ser. No. 08/826,435 (224/302), filed Mar. 20, 1997, now abandoned, which is a continuation of application Ser. No. 08/297,289, filed Aug. 26, 1994, entitled “Lumped Element Filters”, issued as U.S. Pat. No. 5,616,539, which is in turn a continuation-in-part of application Ser. No. 08/070,100 filed May 28, 1993, entitled “Lumped High Temperature Superconductor Lumped Elements and Circuits Therefrom” (as amended), issued as U.S. Pat. No. 5,618,777 on Apr. 8, 1997.
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Parent | 10167938 | Jun 2002 | US |
Child | 11018488 | US | |
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Child | 08885473 | US | |
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Child | 08297289 | US |