Superconductor technology: apparatus – material – process – High temperature devices – systems – apparatus – com- ponents,... – High frequency waveguides – resonators – electrical networks,...
Reexamination Certificate
2002-01-17
2004-06-15
Lee, Benny T. (Department: 2817)
Superconductor technology: apparatus, material, process
High temperature devices, systems, apparatus, com- ponents,...
High frequency waveguides, resonators, electrical networks,...
C333S09900R, C333S204000, C333S134000, C333S185000, C505S700000, C505S701000, C505S866000
Reexamination Certificate
active
06751489
ABSTRACT:
BACKGROUND OF THE INVENTION
This invention relates to high temperature superconductor (HTS) mini-filters and mini-multiplexers with self-resonant spiral resonators as the building blocks, which have the advantages of very small size and very low cross-talk between adjacent filters.
HTS filters have the advantages of extremely low in-band insertion loss, high off-band rejection, steep skirts, due to extremely low loss in the HTS materials. The HTS filters have many applications in telecommunication, instrumentation and military equipment. However, for the regular design of a HTS filter, the resonators as its building blocks are large in size. In fact, at least one dimension of the resonator is equal to approximately a half wavelength. For low frequency HTS filters with many poles, the regular design requires a very large substrate area. The substrates of thin film HTS circuits are special single crystal dielectric materials with high cost. Moreover, the HTS thin film coated substrates are even more costly. Therefore, for saving material cost, it is desirable to reduce the HTS filter size without sacrificing its performance. Furthermore, for the HTS filter circuits, the cooling power, the cooling time, and the cost to cool it down to operating cryogenic temperature increases with increasing circuits' size. These are the reasons to reduce the HTS filter size without sacrificing its performance.
There is a prior art design to reduce the HTS filters size, i.e. by using lumped circuit” elements such as capacitors and inductors to build the resonator used as the building blocks of HTS filters. This approach does reduce the size of HTS filters. However, it also has problems. First, the regular element inductors such as the spiral inductors shown in
FIGS. 1
a
and
1
b
have wide spread magnetic fields, which reach the region far beyond the inductor and undesirable cross-talk between adjacent circuits. Second, in the lumped circuit filter design, the two ends of the spiral inductor must be connected to other circuit components such as capacitors etc. But one of the inductor's two ends is located at the center of the spiral, which cannot be directly connected to other components. In order to make the connection from the center end of the spiral inductor to another component, an air-bridge or multi-layer over-pass must be fabricated on top of the HTS spiral inductor. They not only degrade the performance of the filter, but also are difficult to fabricate. Third, there are two ways to introduce lumped capacitors: One is using a “drop-in” capacitor, which usually has unacceptable very large tolerance. The other is using a planar interdigital capacitor, which requires a very narrow gap between two electrodes with high rf voltage across them, which may cause arcing.
The purpose of this invention is to use self-resonant spiral resonators to reduce the size of HTS filters and at the same time to solve the cross-talk and connection problems.
SUMMARY OF THE INVENTION
One embodiment of the invention is a self-resonating spiral resonator including a high temperature superconductor line oriented in a spiral fashion such that adjacent lines are spaced from each other by a gap distance which is less than the line width; and wherein a central opening in the resonator has a dimension approximately equal to that of the gap distance in each dimension.
Another embodiment of the invention is a high temperature superconductor mini-filter including
a) a substrate having a front side and a back side;
b) at least two self-resonant spiral resonators in intimate contact with the front side of the substrate;
c) at least one inter-resonator coupling mechanism;
d) an input coupling circuit comprising a transmission line with a first end connected to an input connector of the filter and a second end coupled to a first one of the at least two self-resonant spiral resonators;
e) an output coupling circuit comprising a transmission line with a first end connected to an output connector of the filter and a second end coupled to a last one of the at least two self-resonant spiral resonators;
f) a blank high temperature superconductor film disposed on the back side of the substrate as a ground plane; and
g) a blank gold film disposed on the blank high temperature superconductor film.
In another embodiment of the invention, the mini-filters have a strip line form and further include:
a) a superstrate having a front side and a back side, wherein the front side of the superstrate is positioned in intimate contact with the at least two resonators disposed on the front side of the substrate;
b) a second blank high temperature superconductor film disposed at the back side of the superstrate as a ground plane; and
c) a second blank gold film disposed on the surface of said second high temperature superconductor film.
A further embodiment of the invention is a mini-multiplexer including at least two of the mini-filters with different and non-overlapping frequency bands; a distribution network with one common port as an input for the mini-multiplexer and multiple distributing ports, wherein one distributing port is connected to a corresponding input of one mini-filter; and a multiple of output lines, wherein each output line is connected to a corresponding output of one mini-filter.
A further embodiment of the invention is a high temperature superconductor mini-filter including:
(a) a substrate having a front side and a back side;
(b) at least two self-resonant spiral resonators in intimate contact with the front side of the substrate, each of said resonators independently comprising a high temperature superconductor line oriented in a spiral fashion (i) such that adjacent lines are spaced from each other by a gap distance which is less than the line width; and (ii) so as to form a central opening within the spiral, the dimensions of which are approximately equal to the gap distance;
(c) at least one inter-resonator coupling;
(d) an input coupling circuit comprising a transmission line with a first end connected to an input connector of the filter and a second end coupled to a first one of the at least two self-resonant spiral resonators;
(e) an output coupling circuit comprising a transmission line with a first end connected to an output connector of the filter and a second end coupled to a last one of the at least two self-resonant spiral resonators;
(f) a blank high temperature superconductor film disposed on the back side of the substrate as a ground plane;
(g) a film disposed on the blank high temperature superconductor film as the contact to a case for said mini-filter;
(h) a superstrate having a front side and a back side, wherein the front side of the superstrate is positioned in intimate contact with the at least two resonators disposed on the front side of the substrate;
(i) a second blank high temperature superconductor film disposed at the back side of the superstrate as a ground plane; and
(j) a second film disposed on the surface of said second high temperature superconductor film as a contact to a case for said mini-filter.
A further embodiment of the invention is a high temperature superconductor mini-multiplexer including:
(a) at least two mini-filters, each mini-filter having a frequency band which is different from and does not overlap with the frequency bands of each other mini-filter;
(b) a distribution network with one common port as an input for the mini-multiplexer and multiple distributing ports, wherein one distributing port is connected to a corresponding input of one mini-filter; and
(c) a multiple of output lines, wherein one output line is connected to a corresponding output of one mini-filter;
wherein each of said at least two mini-filters comprises:
(d) a substrate having a front side and a back side;
(e) at least two self-resonant spiral resonators in intimate contact with the front side of the substrate, each of said resonators independently comprising a high temperature superconductor line oriented in a spiral fashion (i) such that adjacent lines are spaced from each other by a gap di
E. I. du Pont de Nemours and Company
Lee Benny T.
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