Patent Grant
10396853
The present disclosure relates to communication systems using surface wave propagation, and to transmission arrangements for transmitting and receiving surface waves over a surface wave conduit such as an overhead power line wire.
In next generation mobile access systems, there is a need for densification of the radio base stations (RBS) that connect mobile users and devices to the mobile core network. A major issue with densification in a city environment is to find sites for mounting radio base stations. The conventional approach of mounting RBSs on roof tops and towers will not always be viable, since it is difficult to, e.g., negotiate contracts with so many property owners.
An attractive solution is to approach owners of existing city environment infrastructure, such as utility poles, light poles, street furniture etc. where there is a single owner that can provide installation space in many locations with a single contract. However, it may be difficult to provide backhaul to RBSs that sit in locations where there are no fiber connections available.
Microwave point-to-point links can be used to backhaul radio base stations. However, frequency licenses can be difficult and costly to obtain.
Surface waves and surface wave transceiver systems have been investigated for a long time, but never brought to commercial success due to lack of viable applications as well as technical difficulties. Surface waves transmission involves transmitting a signal by exciting the surface wave on the outside of a conduit. Surface wave reception involves receiving a signal by receiving a surface wave propagating on the outside of a conduit.
U.S. Pat. No. 2,685,068 discloses a surface wave transmission line.
U.S. Pat. No. 7,009,471 discloses a launch apparatus for launching a surface wave onto a single conductor transmission line.
The present disclosure provides improved surface wave transmission systems and converters, as well as methods for improved surface wave transmission and reception.
A surface wave converter is provided for transmitting electromagnetic surface wave signals via a surface wave conduit. The surface wave converter comprises an input port, an interface, and a plurality of waveguide adapters. The input port is configured to receive an input signal. The plurality of wave guide adapters are for mounting along a circumference of the surface wave conduit. The waveguide adapters are configured to jointly excite a surface wave on the surface wave conduit based on the input signal. The interface is configured to distribute the input signal received on the input port of the surface wave converter over the plurality of waveguide adapters via respective waveguide adapter ports.
One purpose of the disclosed surface wave converter, or surface wave launcher, is to make the surface wave evolve in as short a distance as possible on the conduit by creating an electromagnetic field in the surface wave converter output that is as similar as possible to the desired surface wave. Rapid evolution of the surface wave is important in order to reduce coupling loss to the surface wave as well as minimizing coupling to air. This is here achieved by having multiple waveguide adapters mounted around a circumference of the conduit. These waveguide adapters are then connected to an interface which distributes the signal power between the waveguide adapters mounted on the conduit. The plurality of waveguide adapters and the distributing interface thereby provide improved transition between electrical signal and surface wave, and also a smoother field around the conduit.
In other words, the disclosed surface wave converter aims to reduce the loss in the conversion from cable to surface wave. This is achieved by making the surface wave evolve as quickly as possible on the wire, i.e., in a short distance from waveguide adapter to fully evolved surface wave. Reducing the loss also means that radiation into air is reduced and also that pickup of inbound radio waves, i.e. interference, is reduced.
An advantage of the proposed surface wave converter is that it produces a better electromagnetic field for exciting the surface wave around the conduit compared to known surface wave launchers, and thus minimizes the loss and potential coupling to air waves compared to previous solutions.
Also, since it uses discrete waveguide adapters it can be made foldable for easy mounting on top of an existing wire.
Furthermore, the plurality of waveguide adapters can be quite small, thus minimizing protrusions from the conduit.
In one or more embodiments herein, the waveguide adapters are arranged evenly spaced along the circumference of the surface wave conduit. For instance, in an embodiment, the waveguide adapters constitute three waveguide adapters arranged 120 degrees apart along the circumference of the surface wave conduit. The evenly spaced waveguide adapters allow better matching between generated electromagnetic field and propagating surface wave. It is, however, appreciated that the disclosure is not limited to evenly spaced waveguide adapters, but can also be applied to unevenly arranged waveguide adapters.
In one or more embodiments herein, the surface wave conduit is a power line wire. In some parts of the world, e.g. North and South America, it is common to have utility poles along the streets for holding power line wires, transformers and other equipment related to power supply for nearby homes and businesses. These power line wires could serve as conduits for backhauling transmission and reception of surface waves.
In one or more embodiments herein, the waveguide adapters are configured to electromagnetically match a transition between an electrical signal at the interface and a surface wave on the surface wave conduit. Thus, by arranging adapters to match the transition between electrical signal and surface wave, improved electromagnetic properties of the surface wave is obtained. For instance, a return loss and an insertion loss performance of the system is improved by the matching. A system gain is also improved by the disclosed surface wave converter.
In one or more embodiments herein, one or more waveguide adapters comprise open-ended coaxial cables. By implementing the adapters using open-ended coaxial cables, simple and cost-efficient waveguide adapters are obtained. The open-ended coaxial cables are, for example, cut off coaxial cables, or an unterminated end of a waveguide.
In one or more embodiments herein, the waveguide adapters are configured in a fixture. The fixture is configured to maintain relative positions of the waveguide adapters on the circumference of the surface wave conduit. Advantageously, the fixture simplifies installation in that the plurality of waveguide adapters need not be individually mounted on the conduit since they are held together and in place by the fixture.
Also, as will be discussed in more detail below, the fixture optionally is used to galvanically isolate the waveguide adapters and the interface from the conduit. The conduit is a power line wire associated with high voltage. Also, optionally, the fixture is used to improve a matching between the waveguide adapters and the conduit. This way a transition from electrical signal to surface wave is improved which results in better performance with respect to, e.g., insertion loss and return loss characteristics.
Optionally, as discussed in more detail below, the fixture comprises a dielectric element in which the plurality of waveguide adapters are embedded. For instance, the dielectric element can have a shape for matching an electromagnetic transition between the plurality of waveguide adapters and the surface wave conduit.
In one or more embodiments herein, the fixture is separable into two or more pieces, wherein the two or more pieces are configured to enclose and to hold the surface wave conduit when mounted on the surface wave conduit. This simplifies installation of the converter, particularly if the separable pieces of the fixture are configured with an optional hinge and locking mechanism. Hereby, the plurality of waveguide adapters is mounted around, e.g., a wire, to facilitate quicker evolution of a surface wave onto the wire, enabling lower loss and low coupling to air. The concept also, by the fixture, allows for quick and secure mounting onto, e.g., a high voltage wire. In one or more embodiments herein, a quickly evolving surface wave is a surface wave which forms in a short distance measured from the origin, i.e., from a waveguide adapter.
In one or more embodiments herein, the interface comprises an active or a passive power splitter device configured to distribute the input signal received on the input port over the plurality of waveguide adapters.
In one or more embodiments herein, the interface comprises one or more phase shifters, each phase shifter being configured to shift a phase of a signal output from a respective waveguide adapter in dependence of a phase shift configuration. The optional phase shifters improve performance of the system in that the generation of the surface wave is calibrated or controlled to maximize performance.
In one or more embodiments herein, the input signal is an electrical or optical signal, and the surface wave converter is configured to convert the electrical or optical signal to an electromagnetic surface wave.
There are also disclosed herein methods, computer programs, computer program products for surface wave converters, and communication systems comprising surface wave conduits and one or more surface wave converters associated with the above-mentioned advantages.
The present disclosure will now be described in more detail with reference to the appended drawings, where
Aspects of the present disclosure will now be described more fully with reference to the accompanying drawings. The different devices, computer programs and methods disclosed herein can, however, be realized in many different forms and should not be construed as being limited to the aspects set forth herein. Like numbers in the drawings refer to like elements throughout.
The terminology used herein is for describing aspects of the disclosure only and is not intended to limit the invention. As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise.
A surface wave converter converts an electrical field in, e.g., a coaxial cable or a microwave waveguide, into a surface wave that propagates and sustains along a conduit, such as a wire. Unlike an electromagnetic field inside a wire or waveguide, the surface wave exists and propagates on the outside of a conduit such as a wire or surface. The surface wave converter can be implemented in a low complexity fashion using, e.g., an open-ended or cut coaxial cable ending on top of the wire.
A challenge with surface wave transmission and reception is to keep the loss, i.e., insertion loss and return loss, low between the input electromagnetic field and the evolved surface wave. The loss is also partly associated with radiation into air waves where part of the signal energy is radiated as from a conventional radio antenna. This is highly undesirable since energy leaked into air can interfere with other radio equipment in the area and when the surface wave converter is used to convert an incoming surface wave into conventional electromagnetic signal, it may pick up other radio signals that can cause interference with the surface wave signal. Thus, an important aspect to consider when designing a surface wave system is the minimization of coupling between surface wave and airwave radiating radio signals into air.
A conduit of the surface wave is a medium along which the surface wave propagates. This conduit is often a wire. In other cases, the conduit is a surface or some other conduit. Herein, the terms conduit and wire will be used interchangeably, which interchangeable use is not intended to limit the disclosure.
There is a communications interface 104 which, e.g., is a location where a fiber connection interfaces with a core network. The fiber connection is connected to a first wireless access point 102a. This first wireless access point 102a therefore has direct access to fiber backhaul and is not in need of any further backhauling.
However, a second wireless access point 102b is not in direct connection to a fiber connection which can be used for backhauling. To provide backhaul to the second wireless access point 102b, surface wave propagation is used. The first wireless access point 102a is connected to a surface wave converter 100a, via an optional data link device 103a.
The data link device 103a comprises a modem configured to modulate a data signal for transmission over the conduit 110 and to demodulate a data signal received over the conduit 110.
The wireless access point 102a, or the data link device 103a, transmits signals via the surface wave converter 100a on the conduit 110 as surface waves. The surface waves need to be re-generated at each power line pole. There is configured a bridge comprising two surface wave converter units at each power line pole. At each bridge the surface wave is converted back to electrical signal by a surface wave converter unit, and then converted to surface wave on the next conduit in sequence. Eventually the transmission reaches the second wireless access point 102b, via an optional second data link device 103b. The transmission goes both ways, i.e., also to the communications interface 104 from the second wireless access point 102b.
It is appreciated that the electrical signals in one or more embodiments is partly replaced by optical signals on some interfaces, but that an electrical signal is needed in order to excite the surface wave.
A backhaul signal transmission from the second wireless access point 102b towards the communication interface 104 starts out as an electrical signal (or an optical signal). The electrical or optical signal passes via a second data link device 103b configured as interface between the wireless access point 102b and the rest of the surface wave communication system 101. The backhauling signal is converted to a surface wave by means of a surface wave converter 100f. The surface wave travels along the conduit 110 until it reaches a pole. The surface wave is here converted by another surface wave converter 100e into electrical signal. The electrical signal is transmitted to a surface wave converter 100d configured on the next power line wire, which generates again a surface wave based on an electrical signal. This process continues until the transmission reaches surface wave converter 100a and the point where the communication interface 104 is configured.
To the extent
In one or more embodiments herein, the waveguide adapters 210 are configured to electromagnetically match a transition between an electrical signal at the interface 230 and a surface wave on the surface wave conduit 110. This electromagnetic matching can be achieved in many ways, as the skilled person will realize. For example, the waveguide adapters can be configured with specific shapes for matching the transition between electric signal and surface wave. The waveguide adapters can also be configured in connection with a dielectric element (e.g. a lens arrangement or lenses) configured to improve the matching properties of the waveguide adapters with respect to the surface wave conduit. It is appreciated that the matching is usually frequency dependent. Thus, in one or more embodiments herein, the waveguide adapters 210 are configured to electromagnetically match a transition between an electrical signal at the interface 230 and a surface wave on the surface wave conduit 110 based on a frequency band of operation associated with the surface wave converter 100.
The waveguide adapters can be realized with varying degrees of complexity. For instance, the waveguide adapters 210 are realized by using open-ended coaxial cables. Such waveguide adapters are especially easy to construct and will be very cost-efficient. To improve electromagnetic matching properties, the open-ended coaxial cable, in one or more embodiments herein, is combined with dielectric lens arrangements, or have tapered end sections in order to reduce, e.g., insertion loss and reduce air wave propagation emitted from the waveguide adapters.
As an alternative or complement to the open-ended coaxial cables, waveguides can be used in the same manner. Thus, in one or more embodiments herein, the waveguide adapters use waveguides. The waveguides can be implemented using, e.g., metal pipes carrying microwave signals or dielectric waveguides made of plastic or Polytetrafluoroethylene (PTFE).
An interface 230 is configured to connect an input port 235 of the surface wave converter to the plurality of waveguide adapters 210, thereby distributing an input signal received on the input port 235 over the waveguide adapters. The interface 230 receives an input signal on the input port 235 and distributes the input signal over the waveguide adapters. The interface can be of varying complexity ranging from a passive splitter to an active device comprising signal processing functionality. As is commonly understood signal processing functionality can be implemented by circuits implementing a processor or processing circuit hardware, or software, or a combination thereof. The interface and related aspects will be discussed in more detail below.
Consequently, there is disclosed herein a surface wave converter 100h for transmitting electromagnetic surface wave signals via a surface wave conduit 110. The surface wave converter 100h comprises an interface 230 and a plurality of waveguide adapters 210 for mounting along a circumference 220 of the surface wave conduit 110. The interface 230 is configured to connect an input port 235 of the surface wave converter 100h to the plurality of waveguide adapters 210, thereby distributing an input signal received on the input port 235 over the waveguide adapters. The waveguide adapters are configured to jointly excite a surface wave on the surface wave conduit 110 based on the input signal.
Herein, a surface wave converter in one or more embodiments is referred to as a surface wave launcher. The surface wave conduit is any medium on which a surface wave can propagate, i.e., a wire, a rectangular bar, or a surface. A waveguide adapter is any device configured to excite a surface wave based on an input signal. The input signal in one or more embodiments is electric. Alternatively, the input signal is an optical signal, in which case the waveguide adapter is configured to excite a surface wave based on an input optical signal. To distribute means that the input signal is forwarded to each waveguide converter.
In one or more embodiments, the input signal is evenly distributed among waveguide adapters in terms of power or energy. Alternatively, it is unevenly distributed. To jointly excite a surface wave means that the waveguide adapters together excite the surface wave based on their respective distributed input signals obtained through the distribution of the input signal.
In other words, in one or more embodiments herein, the waveguide adapters 210 are configured in a fixture 310. The fixture is configured to maintain relative positions of the waveguide adapters 210 on the circumference 220 of the surface wave conduit 110. This fixture simplifies mounting of the surface wave converter.
In one or more embodiments herein, the fixture 310 is configured to galvanically isolate the waveguide adapters from the surface wave conduit. This galvanic isolation is convenient when the surface wave converter is used together with a high voltage power line.
As discussed above, dielectric elements can be used to improve a matching between the waveguide adapters 210 and the conduit 110. According to some aspects, the dielectric element is configured with a shape for matching an electromagnetic transition between the waveguide adapters 210 and the surface wave conduit 110. According to some such aspects, the dielectric element acts as a lens when jointly exciting the surface wave by the adapters on the conduit.
The example fixture 310 illustrated is
In one or more embodiments herein, the locking mechanism comprises a lock configured to prevent unauthorized persons from tampering with the surface wave converter. This way, authorized personnel are required to use a key, or a code to release the locking mechanisms when servicing or replacing a surface wave converter.
The examples in
Also, the example surface wave converters shown in
The interface 230 is a passive power splitter configured to distribute the input signal received on the input port 235 over the plurality of waveguide adapters. The interface 230 alternatively could be a more advanced active power splitter configured to distribute the input signal received on the input port 235 over the plurality of waveguide adapters.
To further control the generation of the surface wave on the conduit 110, optional phase shifters 440 are configured between the interface 230 and the waveguide adapters 210. The phase shifts applied to the signals, i.e., the phase shift configuration, is pre-determined or adaptively determined, e.g., to maximize some performance criterion, such as insertion loss.
In case of pre-determined fixed phase-shifts, the phase shift configuration is for instance determined by computer simulation or laboratory experimentation.
In case of adaptive phase shifts, the phase shift configuration in one or more embodiments is updated regularly based on some optimality criterion. Alternatively, or additionally, the phase shifts are determined by cycling through all possible combinations of phase shifts and selecting the combination which gives best performance in terms of some performance criterion. For example, the performance criterion is an insertion loss or return loss, or amount of radiated air wave measured in terms of power or energy.
The waveguide adapters discussed herein and exemplified in
According to some example signal processing functions, the signals transferred via the input port 235 is filtered by a filter 540. This filter is an analog filter or alternatively a digital filter, in which case an analog to digital converter is comprised in the interface 530. The filter 540 is configured to filter out interference from a frequency band of interest, or to suppress noise. The filter 540 is an example of a filter structure.
According to some example signal processing functions, the interface 530 also comprises an equalizer 550. This equalizer is configured to compensate for multipath propagation and reflection effects causing signal distortion. The equalizer is updated based on an error signal determined based on the transmitted or received surface wave signals, or it is updated using a blind method such as, e.g., constant modulus equalizer update. The equalizer 550 is an example of a filter structure.
The filter structures 540 and 550 are shown in
The processing circuitry 610 is provided using any combination of one or more of a suitable central processing unit CPU, multiprocessor, microcontroller, digital signal processor DSP, etc., capable of executing software instructions stored in a computer program product, e.g. in the form of a storage medium 630. The processing circuitry 610 is further provided as at least one application specific integrated circuit ASIC, or field programmable gate array FPGA. For instance, the processing circuitry 610 in one or more embodiments is used to provide the phase shifting functionality or signal processing functions described herein.
Particularly, the processing circuitry 610 is configured to cause the interface 230 or 530 to perform a set of operations, or steps. For example, the storage medium 630 stores the set of operations, and the processing circuitry 610 is configured to retrieve the set of operations from the storage medium 630 to cause the interface to perform the set of operations. The set of operations is provided as a set of executable instructions. Thus, the processing circuitry 610 is thereby configured to execute methods as herein disclosed, such as the methods discussed below in connection to
In one or more embodiments, the storage medium 630 comprises persistent storage, which, for example, can be any single one or combination of magnetic memory, optical memory, solid state memory or even remotely mounted memory.
The interface 630 further comprises an interface module 620 for communications with at least one external port. As such the interface module 620 comprises one or more transmitters and receivers, comprising analogue or digital components and a suitable number ports for wireline or wireless communication.
The processing circuitry 610 controls the general operation of the interface, e.g., by sending data and control signals to the interface module 620 and the storage medium 630, by receiving data and reports from the interface module 620, and by retrieving data and instructions from the storage medium 630. Other components, as well as the related functionality, of the interface are omitted in order not to obscure the concepts presented herein.
The above discussion has mainly been focused on transmission of surface waves based on input signals to the surface wave converter. However, it is appreciated that all functions and features discussed above can also be used for receiving surface waves via surface wave conduits. Thus, in one or more embodiments herein, the surface wave converter is also configured for receiving electromagnetic signals via the surface wave conduit 110. The interface 230, 530, 630, or 730 is configured to connect the plurality of waveguide adapters to an output port 520 of a surface wave converter. The plurality of waveguide adapters 210 are configured to jointly receive a surface wave on the surface wave conduit 110 and to output the received signal on the output port 520.
Thus, the surface wave converter is, in one or more embodiments herein, configured for bi-directional communication via the surface wave conduit. The waveguide adapter ports 236 are then bi-directional ports configured to transfer signals to and from the waveguide adapters and the interface.
The bridging element 710 optionally comprises signal processing functionality to condition the signal prior to re-transmission. In one or more embodiments, the bridging element is a wireless access point as discussed above. For instance, the bridging element 710 comprises one or more of a wireless access point 720, processing circuitry 730, and operations and maintenance functionality 740 for, e.g., fault monitoring.
The processing circuitry 730 is provided using any combination of one or more of a suitable central processing unit CPU, multiprocessor, microcontroller, digital signal processor DSP, etc., capable of executing software instructions stored in a computer program product, e.g. in the form of a storage medium 750. The processing circuitry 730 is further provided as at least one application specific integrated circuit ASIC, or field programmable gate array FPGA. For instance, the processing circuitry 730 in one or more embodiments is used in conjunction with or to provide the signal processing functionality, wireless access point 720 operations and maintenance functionality 740, or both as described herein.
Particularly, the processing circuitry 730 is configured to cause the bridging element 710 or components of the bridging element 710 to perform a set of operations, or steps. For example, the storage medium 750 stores the set of operations, and the processing circuitry 730 is configured to retrieve the set of operations from the storage medium 750 to cause the bridging element 710 or components of the bridging element 710 to perform the set of operations. The set of operations is provided as a set of executable instructions. Thus, the processing circuitry 730 is thereby configured to execute methods as herein disclosed.
In one or more embodiments, the storage medium 750 comprises persistent storage, which, for example, can be any single one or combination of magnetic memory, optical memory, solid state memory or even remotely mounted memory.
To emphasize that the present disclosure is not limited to any particular arrangements in terms of number of waveguide adapters 210, distribution of waveguide adapters along the circumference of the conduit 110, or conduit geometry, some additional example waveguide adapter configurations are illustrated in
It is appreciated that the power distribution between waveguide adapters is not necessarily uniform. An unequal power distribution is useful in some cases, depending on, e.g., waveguide geometry.
In one or more embodiments herein, the method 1300 is also for receiving electromagnetic signals via the surface wave conduit 110. The method then comprises connecting S3 the plurality of waveguide adapters to an output port 520 of the surface wave converter via the interface 230, jointly receiving S6 a surface wave on the surface wave conduit 110 by the plurality of waveguide adapters 210, and outputting S7 a received signal on the output port 520.
| Number | Name | Date | Kind |
|---|---|---|---|
| 2685068 | Goubau | Jul 1954 | A |
| 7009471 | Elmore | Mar 2006 | B2 |
| 9998172 | Barzegar | Jun 2018 | B1 |
| 20050111533 | Berkman et al. | May 2005 | A1 |
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