The present invention generally relates to antenna networks and antenna feed circuits and, more specifically, to novel systems and methods for interconnecting a sequence of antennas and antenna feed circuits for implementing a self-assembled antenna network.
Distributed sensor systems used for the industrial internet of things (“IIoT”) often employ a central receiver and processing system connected to multiple antennas by antenna cables. Each antenna may be associated with, and may be located in close proximity to, one or more assets being monitored by sensors in the IIoT system.
The distributed sensor system 100 includes a network of antennas 130a, 130b, and 130c distributed throughout the geographic area and configured to communicate with the distributed set of sensors 140a, 140b, and 140c. As shown, each antenna 130a-c is positioned to receive wireless signals transmitted from one or more sensors 140a-c located in relatively close proximity to their respective assets being monitored. Cables 120a, 120b, and 120c are used to connect each antenna 130a, 130b, and 130c to a corresponding input connection 115a, 115b, and 115c at a central receiver and processing system 110. Each cable 120a-c provides a physical transmission medium for carrying signals from a corresponding antenna 130a-c to the central receiver and processing system 110. Each cable 120a-c may, for example, consist of a conventional coaxial cable.
When the antenna locations in such distributed sensor systems are fixed and known, it is possible for the central receiver and processing system to deduce information about the location of a sensor based on which antenna(s) can observe the sensor. It is also possible for the central receiver and processing system to analyze sensor data that it receives from an antenna as being related to the health of an asset associated with the antenna. Traditionally such a distributed sensor system requires an administrator (or “installer”) to manually configure the system by connecting the plurality of cables from the central receiver to each of the plurality of antennas with the attendant chance of mistakenly crossing their connections.
In prior-art systems, installers place antennas as needed to provide signal coverage over an area and run individual cables from each antenna back to a corresponding input connection at the central receiver as
In a specific example, a distributed sensor system uses wireless sensors to monitor the health of a high voltage switchgear. The switchgear consists of multiple compartments separated by metal barriers with each compartment containing a plurality of sensors and at least one antenna. During installation, each cable is first connected between one of the antennas and the receiver, then the signal integrities of the sensors are tested. This often requires adjustment of antenna locations. When a mistake is made in assigning antennas to different input connections at the central receiver, the installer is misinformed as to which antenna requires adjustment of its location. This simple mistake can dramatically extend the installation time, which necessarily is performed during a forced power outage.
Even when the system appears to function as planned, if the sensors are analog and cannot be positively identified—that is, when only antenna location is used to identify and distinguish otherwise identical sensors based on their locations near different antennas—critical operational and safety data transmitted by the sensors may be attributed to the wrong measurement location. Often the central receiver collects sensor data from multiple, adjacent switchgear, and the response to a detected abnormal condition is to take the affected switchgear out of service for inspection and repair. In the case of a cable wiring error at the receiver, the wrong equipment would be serviced. At a minimum, this would result in wasted time and expense. At the worst, the asset with anomalous conditions could fail despite a warning from the sensor because the wrong switchgear unit was inspected.
In other distributed sensor systems using nonstationary equipment, it is common to deduce the location of equipment based on which antenna or antennas in a network can measure the sensor located at or close to the equipment. Again, a mistake in cabling of the antenna network can lead to faulty location data.
Returning to the example of a switchgear system, often a plurality of antennas, and therefore a plurality of cables, must be routed from the central receiver to a single switchgear compartment. In many cases, only a single signal channel may be transmitted in each of these cables, and it is not always possible to route a sufficient number of cables. As used herein, a “signal channel” generally refers to a physical or logical channel used to transmit a signal. For example, a signal channel may correspond to one or more physical transmission mediums, such as metal wires and/or optical fibers, used to transmit a balanced or unbalanced signal. For example, a signal channel may correspond to a shielded twisted pair (“STP”) used to transmit a signal carrying sensor data from an antenna to the receiver. A signal channel alternatively may be implemented as a logical channel, such as corresponding to one or more predefined time slots or frequencies of a time-division or frequency-division multiplexed transmission. Accordingly, it is possible that a cable routed to an antenna in a switchgear compartment may only support a limited number of signal channels, although a plurality of additional signal channels would be needed to monitor sensor data from all of the sensors in that compartment.
In view of these limitations, prior-art solutions used cable splitters and couplers. These solutions divided a cable's signal power among various antennas, allowing multiple signal channels carried in a single cable to be split one or more times and coupled to the inputs of a plurality of antennas, for example, located in different switchgear compartments. Using such splitters and couplers, an unused signal channel of a cable from the central receiver routed to an antenna in a first switchgear compartment could instead be used to transmit sensor data received by an antenna in a second switchgear compartment. These solutions, however, had limitations in that the relative locations of individual sensors positioned near antennas along a cable were still unknown. These solutions were also disadvantageous because the signal splitting introduced losses that reduced signal quality of the signal channels used to transmit the sensor data to the central receiver.
There remains a current need for systems and methods that can simplify the installation and configuration of antenna-network topologies for IIoT systems comprising distributed wireless sensors for monitoring assets, such as switchgear used in electrical power generation and distribution systems.
Unlike prior implementations, the disclosed embodiments comprise a plurality of antennas that can be interconnected with each other and with a central receiver in a self-assembling manner, such that antennas can be added, removed, and replaced with minimal configuration. For example, an installer in the disclosed embodiments may connect one or more input connections at the central receiver to a sequence of serially-connected antennas, with the central receiver and each adjacent antenna being connected using interchangeable cable bundles. In this configuration, antennas can be added or removed at any location in the sequence using simple cable connections and without having to rewire the input connections at the central receiver. In some embodiments, the antennas may be interchangeable without loss of functionality in a distributed sensor system.
In accordance with the disclosed embodiments, each antenna has an antenna feed circuit, an input connector, and an output connector. An installer may connect a first antenna's input connector to an input port at the central receiver using a first cable bundle. The antenna's output connector may be connected to the input connector of a second antenna using a second cable bundle. Similarly, the output connector of the second antenna may be connected to an input connector of a third antenna by a third cable bundle, and so on. Advantageously, each of the antennas may be configured to assign a set of output signal channels at its output connector to a set of input signal channels at its input connector (or vice versa) according to a predetermined mapping or pattern. The predetermined mapping or pattern may be statically configured or dynamically determined in the antenna. Each antenna may be further configured to route (direct) signals received from the antenna's feed circuitry to a predetermined signal channel at the input connector. By sharing the same configuration for mapping signal channels between the antennas' input and output connectors and antenna feed circuitry, each antenna can be interchangeably positioned in a serially-connected sequence (“chain”) of antennas. The sequence of antennas is self-assembling in the sense that antennas can be easily added, removed, or replaced in the sequence, as each antenna may be configured with the same predetermined mapping between its respective input signal channels, output signal channels, and antenna feed circuitry.
In some disclosed embodiments, a first signal channel at an antenna's input connector may be coupled to the antenna feed circuitry, thereby carrying the antenna's received signal. The antenna may include hardware and/or software for mapping and making connections between the other signal channels at the antenna's input connector relative to one or more signal channels at the antenna's output connector. For example, a second signal channel at the antenna's input connector may be connected to a first signal channel at the antenna's output connector; a third signal channel at the input connector may be connected to a second signal channel at the output connector; a fourth signal channel at the input connector may be connected to a third signal channel at the output connector, and so on. In this manner, the antenna can use its predetermined mapping to route signals and interconnect signal channels between cable bundles connected to the antenna's input and output connectors. In some embodiments, the predetermined mapping may be based on each antenna's indexed location in a chain of antennas, and the likelihood of crossing connections in such embodiments therefore can be significantly reduced.
Further to the disclosed embodiments, an installer may connect a first cable bundle to an input connector at the central receiver, direct or run this first cable bundle to the vicinity of a first asset to be measured at a first location, and connect a first antenna's input connector to the first cable bundle at or close to the first location. One or more sensors at the first location may communicate sensor data about or relating to the condition of the first asset to the first antenna. In addition, the installer may connect a second cable bundle to both an output connector of the first antenna and an input connector of a second antenna, where the second antenna is positioned in the vicinity of a second asset to be measured by one or more sensors at a second location. Additional antennas may be similarly added to form an ordered chain of antennas for receiving sensor data and information relating to a plurality of assets in a distributed sensor system, such as an IIoT system.
According to certain embodiments, the central receiver may be configured to receive the signal channels in the first cable bundle at a communication interface (“port”) having various input connectors. In such embodiments, a first antenna's feed circuitry may route the first antenna's received signals to a first signal channel of the first cable bundle, which the receiver would receive at an input connector corresponding to the first signal channel. The second antenna's feed circuitry may route its received signals to a first signal channel in the second cable bundle, but these signals would then be further routed to a second signal channel in the first cable bundle, which the receiver would receive at an input corresponding to the second signal channel. By logical extension, antenna feed circuitry of the Nth antenna in the chain would route its received signals to a first signal channel of the Nth cable bundle, which would then be further routed to a second signal channel of the (N−1)th cable bundle, a third signal channel of the (N−2)th cable bundle, and so on, including an Nth signal channel of the first cable bundle, which the receiver would receive at an input corresponding to the Nth signal channel.
In some applications and embodiments, it might be desirable to reserve at least one signal channel in the cable bundles for an alternate function. In such embodiments, for example, one or more signal channels in each cable bundle may be dedicated to carrying signals associated with at least one predefined function, independent of the self-assembly of the network of antennas. A signal channel that has been dedicated to a predefined function may, for example, carry control and/or data signals in connection with its associated function. Such signal channels preferably have a one-to-one mapping from each antenna's input connector to its output connector. For example, in some embodiments, at least the Nth signal channel of each cable bundle may be connected to the Nth signal channel in each adjacent cable bundle in the antenna chain and reserved for a predefined function in the antenna network or used to communicate other control and/or status information.
The particular features and advantages of the invention will become apparent from the following description taken in connection with the accompanying drawings in which like reference numbers indicate identical or functionally similar elements. The following figures depict details of disclosed embodiments. The invention is not limited to the precise arrangement shown in these figures, as the accompanying drawings are provided merely as examples:
Each antenna 210a-c may be physically located in the vicinity of one or more assets that are measured by one or more sensors as described above with respect to
In
Each antenna 210a-c comprises a respective input connector 212a-c, output connector 214a-c, and antenna feed circuitry 216a-c. Each input and output connector is configured to send and/or receive signals over signal channels of a cable 225 or cable bundle 220a-c. As used herein, a “cable” may consist of any type of physical medium for transmitting one or more signals, such as but not limited to a coaxial cable, shielded or insulated wires, shielded twisted pairs, optical fibers, and so forth; a “cable bundle” more generally refers to one or more cables, which may comprise the same or different types of physical transmission media, supporting a plurality of signal channels. In some embodiments, each signal channel in a cable bundle may correspond to a different physical transmission medium, such as a different shielded twisted pair of wires. In other embodiments, the signal channels in a cable bundle may correspond to any combination of physical and/or logical channels for carrying analog or digital signals. The input and output connectors 212a-c and 214a-c include the interface hardware and logic and associated software for sending and receiving signals over signal channels of a cable or cable bundle. To that end, each of the input connectors 212a-c and output connectors 214a-c includes a corresponding set of inputs (e.g., headers, connectors, or other input terminals) for connecting to one or more physical transmission media in a cable or cable bundle.
In the exemplary embodiment of
Each antenna 210a-c also may comprise one or more physical processors (not shown), such as a microprocessor, microcontroller, digital signal processor, field programmable gate array, application specific integrated circuit, or the like, and may further include at least one non-transitory memory device for storing associated software or firmware, configured to control at least some operations of the input connectors 212a-c, output connectors 214a-c, and/or antenna feed circuitry 216a-c in accordance with the disclosed embodiments described herein.
As
In this exemplary embodiment, the first connector port 205a is connected by a cable bundle 220a to an input connector 212a of an antenna 210a, which may have the same internal connections described below in the exemplary embodiment of
In some disclosed embodiments, each antenna 210a-c is preferably interchangeable in the sequence of antennas and each cable bundle 220a-c is preferably an interchangeable bundle of one or more cables providing a plurality of signal channels. Because the antennas 210a-c and cable bundles 220a-c may be interchangeable, an installer can add, remove, and replace antennas in the system with less configuration than is conventionally required.
In the exemplary embodiment of
In
In this exemplary embodiment, each of the input and output signal channels 1, 2, and 3 are respectively assigned to pairs of wires on the input and output connectors. For example, wires 1 and 2 on the input and output connectors may correspond to signal channel 1, wires 3 and 4 may correspond to signal channel 2, wires 5 and 6 may correspond to signal channel 3, and wires 7 and 8 may be assigned to the special function signal channel in this example. As noted above, each signal channel 1-3 and the special function signal channel at the input and output connectors may be implemented using a different shielded twisted pair in a cable bundle. However, within the antenna 210 the interconnection of the input signal channels and output signal channels may utilize other types of physical transmission media. Those skilled in the art will appreciate that the signal channels may be assigned to any predetermined wire(s) on the input and output connectors in other embodiments. In addition, while
The physical connections for mapping the wires 1-6 between the input and output connectors 212 and 214 in
Advantageously, in the example of
In some embodiments, a plurality of signal channels at the input and/or output connectors may be used to provide signal diversity, for example, where an antenna receives multiple signals from the same or related sensors. In addition, while the assignment of input and output signal-channel numbers to the wire terminals at the input and output connectors is preferably predefined, in some embodiments they also could be dynamically assigned, for example, by a controller (not shown) configured to manage the channel-to-wire assignments.
Referring again to
In the exemplary embodiment of
In some embodiments, each antenna 210 may utilize more than one signal wire or wire pair per signal channel, and the mapping of signal channels between an antenna's input connector and its output connector may be performed by shifting the physical wire connections between the output and input connectors by the number of wires per channel. Such a process for shifting between different sets of wires assigned to channels on input and output connectors may be performed as described, for example, in U.S. patent application Ser. No. 16/580,251, entitled “Antenna connectivity with shielded twisted pair cable,” to J. Andle, filed on Sep. 24, 2019, which is hereby incorporated by reference in its entirety.
In an exemplary case, a CAT-8 shielded twisted pair could have two signal channels defined as a first twisted pair for partial discharge monitoring and a second twisted pair for passive wireless sensor measurements. Since a typical CAT-8 cable comprises four shielded twisted pairs, there are sufficient wire pairs for the two signal channels in this example.
Numerous modifications, changes, and other embodiments of the invention herein disclosed will suggest themselves to those skilled in the art. It is to be understood that the present disclosure relates to certain disclosed embodiments of the invention which are for purposes of illustration and explanation only and are not to be construed as a limitation of the full scope of the invention. All such modifications which do not depart from the spirit of the invention are intended to be included within the scope of the appended claims.
For example, the figures and descriptions in the disclosed embodiments depict a central receiver and antennas that function as receivers; however, the invention described herein applies equally to transmitters, monostatic transceivers, and bistatic transceivers. More generally, the antennas 210a-c may be used to receive and/or transmit signals in an IIoT system. Further, the invention is not limited to any particular antennas, sensors, assets, equipment, or IIoT systems that may have been described for purposes of explanation as examples in the disclosed embodiments.
In addition, the figures and descriptions in some disclosed embodiments depict pairs of wires for each signal channel, which may be twisted pairs or shielded twisted pairs, but the invention is equally applicable using cables and cable bundles comprising other types of physical transmission media for providing the signal channels, including for example single-wire signals referenced to a common ground wire, e.g., unbalanced signals that may be carried on one or more of the signal channels in the cable bundles of the disclosed embodiments. Furthermore, hybrid systems with some differential signals and some single-ended signals may be used in multi-function embodiments. In some embodiments, one or more signal channels in a cable bundle may correspond to shielded twisted pairs that provide balanced transmission media, and the antenna feed circuits may be configured to provide signals from unbalanced antenna structures to the STP balanced transmission media in the cable bundle.
Solely for purposes of discussion and explanation, the input and output connectors 212a-c and 214a-c described with reference to
The disclosed embodiments also depict exemplary antenna signals; however, other signals and systems, for example, considered in the above-identified U.S. patent application, “Antenna connectivity with shielded twisted pair cable,” also may be multiplexed into self-assembled networks using the present invention. For example, while radio frequency (“RF”) signals may be transmitted over the signal channels in the exemplary disclosed embodiments, one or more of the signal channels alternatively may be configured to transmit other types of signals, such as but not limited to optical or microwave signals, where such embodiments also may use converters between different signal channel transmission media.
Those skilled in the art will also appreciate that other modifications and alternatives may be implemented in accordance with the exemplary embodiments described herein. For example, the physical wire connections at the input and output connectors and receiver port may be implemented in various ways, including both direct and/or indirect connections (such as using one or more signal couplers, filters, digital-to-analog converters, analog-to-digital converters, buffers, and so forth. Also, in the exemplary embodiments the antennas may be configured to receive signals from sensors and special devices over wired connections or wireless links using any network or communication standards or protocols. In some embodiments, one or more of the sensors in the IIoT system may be identified with a readable serial number and, further, one or more antennas in the antenna network also may be identified with a readable serial number making them one of the sensors in the IIoT system. In an exemplary embodiment, for example, the central receiver may self-assemble the antenna network based on the internal sensor aspect of each antenna and, in a further exemplary embodiment, the receiver may be configured to validate the installation of the antennas in the network.
Those skilled in the art will further appreciate that while the exemplary embodiments described herein relate to antenna networks employed in a distributed sensor system, the advantages of the inventive self-assembling antenna network is more generally applicable in any system that may employ sequences of antennas as described herein. In some implementations, for example, one or more of the antennas may be part of, integrated with, or otherwise included in another system or device. While the self-assembling antennas in the exemplary disclosed embodiments have been described in the context of distributed sensor systems, such as IIoT systems, the antennas alternatively may be employed in any system or network having transmitters (sensors or otherwise) distributed in a geographic area that communicate with antennas that may be arranged as self-assembling antenna networks described herein.
The present application claims the benefit of priority under 35 U.S.C. § 119(e) to U.S. Provisional Application No. 63/039,232, entitled “Self-Assembling Antenna Networks and Antenna Feed Circuits for Same,” filed Jun. 15, 2020, which is hereby incorporated by reference in its entirety as if fully set forth herein.
Number | Date | Country | |
---|---|---|---|
63039232 | Jun 2020 | US |