The present invention relates generally to structures and techniques for filtering radio waves and more particularly to the implementation of a filter network using a combination of superconducting filters and non-superconducting filters.
Radio frequency (RF) equipment have used a variety of approaches and structures for receiving and transmitting radio waves in selected frequency bands. The type of filtering structure used often depends upon the intended use and the specifications for the radio equipment. For example, dielectric filters may be used for filtering electromagnetic energy in the ultra-high frequency (UHF) band, such as those used for cellular communications in the 800+ MHz frequency range. Typically, such filter structures are implemented by coupling a number of dielectric resonator structures together. One can also use metal coaxial resonators in such filters are coupled together via capacitors, inductors, or by apertures in walls separating the resonator structures. The number of resonator structures used for any particular application also depends upon the system specifications and, typically, added performance is realized by increasing the number of intercoupled resonator structures.
However, because of an increase in the number of users utilizing a limited bandwidth, demand has increased for greater frequency selectivity than can be provided by normal or non-superconducting resonator filters, especially for RF signals in the ultra-high frequency bands used for cellular communications. High frequency selectivity has previously been accomplished using High Temperature Superconducting (HTS) filters, usually as front-end filters for cellular base station receivers. However, HTS front-end filters may be susceptible to failure, or degradation in performance, induced by lightning surges or other high power signals. In addition, the non-linearity of HTS filters produces in-band intermodulation spurious signals from out-of-band interferers.
For cellular or similar base stations, typical lightning protectors have only one resonator and do not provide sufficient protection from high power co-located radio frequency signals originating from the transmit side of the base stations. These co-located transmission signals are especially troublesome because they are relatively closely spaced to the operating frequency of the base station receivers. Accordingly, there is a need for a filter that overcomes the above-mentioned and other disadvantages associated with the prior art.
The present invention is directed toward a filter network that provides high frequency selectivity to a receiver. The filter network of the present invention comprises a non-superconducting filter and a superconducting filter. The output of the non-superconducting filter is coupled to the input of a superconducting filter. The non-superconducting filter pre-filters received RF signals by passing RF signals having a frequency within a first pass band to the superconducting filter. The superconducting filter further filters the RF signals to provide a high degree of frequency selectivity at its output.
The filter network of the present invention is able to provide high frequency selectivity while overcoming many of the disadvantages associated with superconducting filters. This is achieved by pre-filtering the RF signals with the non-superconducting filter before inputting them to the superconducting filter. The non-superconducting filter protects the superconducting filter from lightning surges or other high power signals. In addition, the non-superconducting filter filters out interferers that produce in-band intermodulation spurious signals at the superconducting filter output. In a multiplexed configuration, the non-superconducting filter protects the superconducting filter directly from transmit signal energy.
According to one embodiment of the present invention, the non-superconducting resonator filter comprises a housing enclosing three resonators. The resonators are coupled to each other through apertures in the housing. The effect of using this coupling with the three resonators is to produce a filter response with a pass band and a finite frequency transmission zero located outside the pass band.
Other aspects and advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings in which:
The present invention is believed to be applicable to a variety of radio frequency (RF) applications in which achieving low insertion loss in the pass band with high attenuation in the stop band, and an extremely high degree of selectivity in the pass band are necessary. The present invention is particularly applicable and beneficial for cellular-communication base stations, and other communication applications. While the present invention is not so limited, an appreciation of the present invention is best presented by way of a particular example application, in this instance, in the context of such a communication system.
Now turning to the drawings,
The filter network 100 comprises a non-superconducting filter 20 and a superconducting filter 30, preferable a High Temperature Superconducting (HTS) filter. The input of the non-superconducting filter 20 receives RF signals 15 from the antenna 12. The output of the non-superconducting filter 20 is coupled to the input of the superconducting filter 30, and the output of the superconducting filter is coupled to the receiver 16. The non-superconducting filter 20 pre-filters the received RF signals 15 before they are filtered by the superconducting filter 30.
The non-superconducting filter 20 is a bandpass filter tuned to pass the received RF signals having a frequency within a first pass band to the superconducting filter 30. Preferably, the first pass band encompasses a receiving frequency range of the base station. For base stations using the Advanced Mobile Phone Service (AMPS) standard, for example, the total receiving frequency range is approximately 824 MHz to 849 MHz. The superconducting filter 30 is a bandpass filter tuned to pass the pre-filtered RF signals having a frequency within a second pass band to the receiver 16. The second pass band is a narrow pass band located inside the first pass band for providing high frequency selectivity to the receiver 16.
The non-superconducting filter 20 protects the superconducting filter 30 from high power out-of-band signals that can cause catastrophic failure of the superconducting filter 30. The high power signals include electrical surges caused by lightning strikes. In addition, the non-superconducting 20 filter filters out interferers located outside the first pass band before they are inputted to the superconducting filter 30. This is done because these interferers produce in-band intermodulation spurious signals in the superconducting filter 30. By filtering out these interferers before they are inputted to the superconducting filter 30, the non-superconducting filter 20 dramatically reduces the in-band intermodulation spurious signals.
The superconducting filter 30 provides high frequency selectivity to the receiver 16 for rejecting undesirable signals that are closely spaced in frequency to desirable signals. The advantage of using a superconducting filter is its ability to provide a precise narrow pass band around the desired signals with low insertion loss due to its low resistance. This allows the superconducting filter 30 to provide high frequency selectivity without adversely affecting the signal sensitivity of the receiver 16.
Therefore, the filter network 100 according to the present invention exhibits high frequency selectively and low insertion loss without many of the disadvantages associated with a superconducting filter. This is achieved by pre-filtering the RF signals with the non-superconducting filter 20 before inputting the RF signals to the superconducting filter 30. That way, catastrophic failure due to high power out-of-band signals and performance degradation due to in-band intermodulation spurious signals are dramatically reduced.
Each resonator 215, 220 and 225 is electro-magnetically coupled to each one of the other two resonators 215, 220 and 225 through apertures in the housing 210. The aperture coupling resonators 215 and 220 is shown in
The turning screws 320 are used to adjust the capacitance of the resonators 215, 220 and 225. Turning the tuning screws 320 inwardly increases the capacitance of the resonators 215, 220 and 225, which lowers the resonance frequency of the resonators 215, 220 and 225. Turning the tuning screws 320 outwardly decreases the capacitance of the resonators, which increases the resonance frequency of the resonators 215, 220 and 225.
The non-superconducting filter 200 of
In one specific example of the non-superconducting filter 200 in
In this specific example, the effect of the cross coupling between the resonators 215, 220 and 225 produces a finite frequency transmission zero, which can been seen as a deep spike 375 in the insertion loss 350 in the plot 345. This transmission zero is located inside the base station transmitting frequency range of 869 MHz to 894 MHz and provides enhanced rejection of frequencies within this frequency range.
The transmit filter 420-n filters incoming transmit signals 422-n from the transmitter side of a base station (not shown). The transmit filter 420-n is a bandpass filter constructed to pass signals within a transmitting frequency range of the base station, for example, approximately 869 MHz to 894 MHz for the AMPS standard. The transmit filter 420-n may include one or more finite frequency transmission zeros for providing enhanced rejection of signals located outside of the transmitting frequency range, such as the receive signals on the common antenna port 450-n. The non-superconducting filter 430-n of the receive filter network 425-n pre-filters receive signals from the antenna 460. The non-superconducting filter 430-n is a bandpass filter constructed to pass signals within a receiving frequency range of the base station, for example, 824 MHz to 849 MHz for the AMPS standard. The non-superconducting filter 430n may include one or more finite frequency transmission zeros for providing enhanced rejection of signals located outside of the receiving frequency range, such as the transmit signals on the common antenna port 450-n. The superconducting filter 440-n is a sharp bandpass filter for providing high frequency selectivity of the receive signals. The receive electronics 440-n further processes the receive signals. The receive electronics 440-n may include a Low Noise Amplifier (LNA), which may or may not be cryogenically cooled, for amplifying the receive signals. The receive electronics 440-n may also include protection circuits for protecting the superconducting filter 440-n and/or base station (not shown) from electrical surges. The protection circuits may include gas discharge tube voltage arrestors, quarter wavelength stubs, and any other protection circuits that are well known in the art. The receive signals are outputted 445-n by the receive filter network 425-n to the receiver side of a base station (not shown).
The multiplexer 410 according to the present invention enables the same antenna 460 to both transmit and receive signals, thereby reducing costs. This is achieved by coupling the transmit filter 420-n and the receive filter network 425-n to the common antenna port 450-n of the multiplexer 410, and coupling the common antenna port 450-n to the antenna 460.
The transmit filter 515 filters incoming transmit signals from the base station (not shown) in a manner similar to the transmit filter 420-n of the multiplexer 410. The first non-superconducting filter 530 pre-filters receive signals from the antenna 565 in a manner similar to the non-superconducting filter 430 of the multiplexer 410. The superconducting filter 540 is a sharp bandpass filter for providing high frequency selectivity of the receive signals. The receive electronics 540 further processes the receive signal in a manner similar to the receive electronics 440-n of the multiplexer 410. The second non-superconducting filter 550 is a bandpass filter that passes the receive signals to the common port 570 while blocking the transmit signals on the common port 570 from the entering the receive electronics 540. The second non-superconducting filter 550 may be the identical to the first non-superconducting filter 530.
The double-duplexer 510 according to the present invention enables the same antenna 565 to both transmit and receive signals, thereby reducing costs. In addition, the double-duplexer 510 enables the transmit signals and the receive signals to flow between the double-duplexer 510 and the base station (not shown) through the common port 570. As a result, a single cable 575 can be used to coupled the double-duplexer 510 to the base station. Because the base station uses a single cable 575 to both transmit signals to and receive signals from the double-duplexer 510, additional filters may be needed to split the transmit and receive signals at the base station. This may be accomplished by providing a transmit filter 580 between the transmitter side of the base station (not shown) and the cable 575, and a receive filter 585 between the receiver side of the base station (not shown) and the cable 575.
Although, the double-duplexer 510 was described as including one transmit filter 515 and one receive filter network 520, those skilled in the art will appreciate that any number of transmit filters and receive filter network may be added to the double-duplexer to realize a double-multiplexer.
Additionally, to alleviate catastrophic failure of the receive side of the systems shown in
Other aspects and embodiments of the present invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. For example, the non-superconducting filter illustrated in
This application is a continuation of U.S. application Ser. No. 09/818,100, filed Mar. 26, 2001 now U.S. Pat. No. 6,686,811, allowed, which is fully and expressly incorporated by reference herein.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 09818100 | Mar 2001 | US |
Child | 10430914 | US |