Enclosure for microwave radio transceiver with integral refractive antenna

Information

  • Patent Grant
  • 6462717
  • Patent Number
    6,462,717
  • Date Filed
    Friday, August 10, 2001
    23 years ago
  • Date Issued
    Tuesday, October 8, 2002
    22 years ago
Abstract
An all-weather housing for outdoor microwave radio nodes arranged in a network, each node capable of directing or receiving a beam of microwave energy in a selected direction, the housing including a shroud enclosing a transceiver, antenna, switches, and utilities. Each shroud has a radome projecting from the shroud in line of sight relation to other radomes in the network. A microwave radio transceiver is disposed within the shroud, operating on a scheduled transmission and reception basis in accordance with a schedule provided in a control channel amidst data. A ball-shaped microwave refractive lens is located adjacent to the radome, inside of the shroud, with a curved array of feed ports and switches, with the feed ports communicating microwave energy between the transceiver and the radome through the lens in multiple selected directions.
Description




FIELD OF THE INVENTION




This invention relates to environmental housings for electrical equipment and, more particularly, to an outdoor mounted all-weather enclosure for microwave radio transceivers.




BACKGROUND ART




PCT application WO 00/25485, published May 4, 2000, discloses a broadband wireless network invention by Berger et al. based on mesh topology having a plurality of wireless transceivers operating in the gigahertz range with the ability of adding and dropping data at each transceiver, as well as routing data between multiple wireless transceivers. Transceivers with switches are considered to be nodes, designed to select a transmission direction and a receive direction based upon the routing address of data packets to be sent and received. The selection of a transmission or receive direction is done instantaneously to accommodate short bursts of data packets arriving from nodes located at different directions or transmitted towards nodes located at different directions as defined by a scheduler of the MAC (media access control) layer.




PCT application WO 00/76088, published Dec. 14, 2000, discloses a scheduler and control algorithm for a system as described above. The scheduler is designed to efficiently allow implementation of mesh networks with IP packet data flow between the network nodes or backbone access points. The disclosed MAC protocol features transmission of synchronous schedule information in a control channel between the nodes to assign asynchronous variable length packet data slots in between the schedule information time slots. Available data slots are adaptively assigned by each recipient node to the data initiator node based on requested time slots by the initiator and the available time slots of the recipient.




The mesh topology networks described above operate in the multi gigahertz spectrum, i.e. microwave bands. In 1998, the FCC auctioned a large amount of the radio spectrum in the 27 GHz and 31 GHz bands for use in Local Multipoint Distribution Systems. Similar spectral bands were opened for use in Canada, Australia, New Zealand and Argentina. In Europe, the radio spectrum between 24.5 GHz and 26.5 GHz was also assigned for multipoint use. Many countries are in the process of opening different bands at the high frequency spectrum between 10 GHz and 40 GHz for use on a territorial basis rather than on a link per link basis, as in the past. This main difference of approach in licensing the radio spectrum enables the network operator to build a network, which covers a large topographical area and offers connectivity services to those customers in line of sight relation in the area. This is because millimeter wave transmission depends on line of sight between communicating transceivers. An arrangement of devices as described above is shown in PCT international patent application PCT/US00/15482, published Dec. 14, 2000.




Another type of radio system operating in the same spectral region is the point to multipoint network. Such a system employs a simpler MAC layer because of the broadcast nature of the downstream link and the polling of the upstream link. When the base station transmits in a certain frequency and time slot, all the customers in the sector except the one that receives information are blocked from receiving any information. In the upstream direction, only one customer can transmit at a certain time on a certain frequency.




For these types of communications systems, an object of the invention was to provide a rugged, durable, mast-mounted, all-weather radio housing. Such a housing must allow multiple directional beams of millimeter waves to be transmitted to nodes dispersed over wide angles, i.e. typically wider than 90 degrees, for line of sight communication between nodes.




SUMMARY OF INVENTION




The present invention is a fixed weather-tight enclosure, acting as a housing for a wireless node, including a microwave radio transceiver in an adaptive wireless network, such as a mesh topology network, capable of sending and receiving energy in multiple directions. The enclosure features an exterior shroud, having an elliptical cross section for shedding rain and snow. The overall appearance of the unit is almost egg-shaped, with a maximum dimension of about one-half meter. The enclosure protectively shields an exposed bullet shaped radome, similar to the type used on aircraft fuselages, pointed in line of sight relation to one or more other similar enclosures. Other enclosures communicate with each other on the same basis. Each enclosure provides environmental protection for a passive curved microwave radio refractive lens acting as a non-resonant antenna capable of transmitting and receiving in selected directions. This lens receives and refractively bends electromagnetic energy from or to a curved array of feed ports, proximate to the curved surface of the lens element, so that the antenna can selectively transmit radiation in desired directions, depending upon the particular radio frequency feed ports providing energy to the refractive element. The radome provides sufficient clearance to allow passage of beams or signal lobes over various angles typically exceeding 90 degrees in spread with beam widths of a few degrees. A microwave radio transceiver, the microwave refractive lens, the array of feed ports and support circuits all fit within the enclosure.




The enclosure is mounted on a mast by a bracket attached to heat sink fins on the rearward portion of the shroud. The bracket allows angular adjustment, both horizontally and vertically, of the pointing direction of the radome.




The shroud has two major compartments. A first compartment is the body which houses the supports for the microwave lens, switches, fan and heater, and the feed element array. The second compartment surrounds the first compartment and has the power supply, transceiver, motherboard, and a second radio for local communication, control, and utility circuits. The second compartment, being made of thermally conductive metal, preferably aluminum, defines heat sink fins in the rear of the shroud body. A small door, also in the rear of the shroud body, gives access to power and data cables, as well as wires, leading into the interior of the second compartment. Access to the unit power supply is through the same small door so that disassembly of the entire unit is not needed to check or repair the power supply.




Within the first compartment, an electrical heater, a fan and a control circuit operate to circulate warm air within the radome with sufficient capacity to avoid accumulation of frost or ice on the exterior surface of the radome. An interior partition within the shroud provides support for the base of the radome. The partition has a central aperture allowing the microwave lens to extend from the rearward portion of the shroud into the radome. Also with the first compartment is a support frame having spaced apart sockets for securing the microwave lens. The lens, in the preferred version, is ball shaped and has spaced apart protuberances on opposite sides of the ball shape, which fit into the sockets in an interlocking manner.




A network of similar enclosures mounted on masts or high locations relay data among themselves according to schedules in a control channel transmitted with the data. Enclosures having several other enclosures in a line of sight relation may select the direction of transmission, depending on addresses contained within the control channel of information received. The protective shroud in each enclosure helps establish an all weather-operating environment for mast mounted microwave transceivers.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a perspective view of an all weather, mast mounted, enclosure for a microwave radio transceiver in accordance with the present invention.





FIG. 2

is an enlarged perspective view of the enclosure shown in FIG.


1


.





FIG. 3

is a cross-sectional view of the interior of the enclosure shown in

FIG. 1

, taken along lines


3





3


.





FIG. 4

is a rear perspective, view of the enclosure of

FIG. 1

illustrating mast-mounting details.





FIG. 5

is an electrical operational view of refractive lens element used inside of the enclosure of

FIG. 1

in accordance with published PCT Application WO 01/28162 Apr. 19, 2001.





FIG. 6

is a plan view of a radio network employing a plurality of enclosures of the kind shown in FIG.


1


.











BEST MODE FOR CARRYING OUT THE INVENTION




With reference to

FIGS. 1 and 2

, an all-weather enclosure


10


is shown having a shroud


11


, enclosing electronic components, including a radio transceiver, sending and receiving electromagnetic energy through radome


15


. The general cross-sectional shape is elliptical, with the rounded surfaces shedding rain and snow. The enclosure is mounted on mast


13


, which is supported, from earth E, or from a structure. The enclosure emits microwave beams


17


in selected directions, towards other similar enclosures in radio line of sight relation, depending upon information contained in messages handled by the radio transceiver within the enclosure.




In

FIG. 2

, shroud


11


may be seen to have an upper section


21


overhanging the radome


15


and acting as a brim to keep rain or snow, falling vertically, from hitting the radome and sticking to it. Upper section


21


of shroud


11


extends over the profile of the radome in preferred instances, but at least over a portion of the exposed radome. The front face of the shroud has a scooped section


23


which is a curve revolved about an axis. The overhang terminates in a lower outer cover


25


which is joined to a back section


27


which encloses most of the electronic components. The back section is linked via door


65


, in

FIG. 3

to the upper outer cover


21


. The radome


15


may be seen to have a rounded convex, bullet-shaped nose pointing in a fixed direction relative to the shroud.




With reference to

FIG. 3

, the shroud is seen to have upper cover


21


overhanging the radome


15


. The radome acts as a protective enclosure for microwave refractive lens


31


which focuses microwave energy from a plurality of feed ports


51


associated with a plurality of switches


53


(Described in PCT Application WO 01/28162 Apr. 19, 2001) which are actuated by routing instructions within radio messages as explained in the above-mentioned international patent applications. The feed ports are microwave transmission guides disposed in an arc, following the contour of the lens


31


and in close proximity. Each feed port is at a slightly different angle to an axis of the lens


31


for the purpose of directing microwave energy in different selected directions. Each radome has an axis of symmetry.




The switches


53


controlling the feed ports


51


derive energy from a microwave radio transceiver


55


which may be a known type of transceiver mounted to a backing member


71


. The backing member forms a portion of a second compartment, within the enclosure, mounting motherboard


61


at an inclined angle and also mounting power supply


63


, facing outwardly, toward a door


65


having outwardly facing heat sink fins


66


, described below. The backing member


71


is joined to a lower inner cover


45


, which, in turn, is joined by means of an O-ring seal


43


to the base


41


of radome


15


. Lens


31


has protuberances


32


and


34


projecting outwardly and interlocking with lens support members


33


and


35


, respectively.




The curved array of feed ports direct microwave energy into lens


31


at various trajectories selected by control circuitry. Switches


53


select a specific port for feeding or receiving energy to or from lens


31


. The energy originates or is directed to a radio transceiver


55


mounted against backing member


71


.




A fan


57


moves air warmed by a heater in the vicinity of the lens and directs it toward the radome


15


where the warm air serves to clear any ice or frost, which may cling to the outer surface of the radome. A control circuit, such as an automatic thermostat, regulates temperature by regulating the operation of the heater


59


. A motherboard


61


which may include the control circuit is mounted at an angle to the backing member. A diagonal bulkhead


44


adds internal strength to the shroud and serves to anchor the lens support members


33


and


35


, as well as the inner cover


45


and


47


.




Radome


15


has a base


41


, which is secured by means of an O-ring seal


43


to the forward or first compartment of the bulkhead. The forward or first compartment of the shroud includes the lens


31


, the feed ports


51


, the switches


53


, and the wall members


42


and


44


. An inner cover


47


and the lower front cover


45


uses the annular seal


43


to provide a closure within the shroud for the second compartment containing electronics equipment. Lens


31


is inside the first compartment, with the radome


15


being part of the shroud. Note that the second compartment wraps around, or envelops, the first compartment, with the shroud enveloping both compartments. The bulkhead


42


and


44


may optionally include RF shielding material to prevent non-focused microwave energy from entering the space behind the bulkhead, i.e. entering the second compartment. In other words, the upper section


21


is on the radome side of the seal


43


. A space


69


, just above the outer cover


45


, is provided for a second radio transceiver


68


which may provide local communication by means of an antenna


72


. The second radio transceiver is optional and is used for local communication, for example, in the ISM, MMDS, UNII, etc bands. Door


65


provides access to the input/output board and power supply


63


, inside of the shroud. Multiple cables may pass through a seal in the door and compartment, including a power cable, a data cable and a fiber-optic, high-speed data cable.




It should be noted that the upper outer cover


21


and the lower outer cover


25


may be integrally formed of a single piece of material. Similarly, the bottom inner cover


45


and the upper inner cover


47


can be integrally formed of a single piece of material.




With reference to

FIG. 4

, the back section


27


of shroud


11


has fins


66


which are parallel, spaced apart members formed integrally with the back section


27


. The spacing between fins is uniform and into the space between two adjacent fins, a pair of stanchions


91


are placed to firmly attach to the standoff bracket


87


. The standoff bracket has a distal end mounting a compression back member


85


, which may be curved to receive mast


13


. Compression bracket caps


81


secure the mast


13


to the bracket back member


85


by means of machine screws


83


, which pass through both the bracket cap


81


, and the bracket back member


85


. By rotating the compression back member horizontally relative to the mast, angular adjustments may be made in the horizontal plane, indicated by the arrow H in FIG.


4


. Stanchions


91


pivot about screw


90


, with a slot


92


in plate


87


allowing screw


94


to lock the plate after allowing vertical angular adjustment of the shroud relative to the mast. In other words, the shroud is adjustable in its vertical angle and horizontal angle relative to the mast, which is generally fixed. Once adjusted, the radome is in a fixed position. Power cable


91


, signal wire cable


92


and fiber optic cable


93


communicate with the housing from exterior sources. The cables follow grooves between fins


66


and enter the housing through entry holes


94


,


95


and


96


, respectively, at the base of door


66


.




In

FIG. 5

, described more fully in PCT patent application WO 01/28162, published Apr. 19, 2001, by the applicant who is the assignee of the present invention, the microwave lens


31


may be seen in an operational, sectional view near radome


15


. The concentric circles in the lens


31


represent material of changing refractive index. Such a lens is known as a graded index lens, such as a Lunenburg, or Morgan lens, and serves to form a microwave beam, or to receive microwaves from a selected direction. A number of feed ports


116


,


117


, and


118


, plus others, are located about the rearward circumference of lens


31


to provide microwave energy to form beams in selected directions. The feed ports determine the angular orientation of beams emitted from the front of radome


15


. Similarly, the feed ports accept energy, which is focused by the lens


31


in preferential directions after passing through the radome


15


. A number of switches in the switch box


119


route the directionality information to the appropriate feed element. The switch box


119


electrically communicates with transmitter section


120


and receiver section


121


of a transceiver associated with the local network node. Control circuitry


122


receives and transmits information locally along cable


123


. This information contains both the control channel and data channel, which must be read by the control circuitry for implementation of the scheduling algorithm, which is part of the MAC protocol.




Microwave beam


112


may be seen to be associated with feed port


117


, while beams


113


and


114


may be seen to be associated with feed ports


116


and


118


, respectively. The beams may be seen to be focused by the lens


31


, in a refractive manner, to the associated feed element. Using lens


31


, the feed ports impart a selected directionality to the beams. The beams are seen to pass through the radome


15


, which provides a protective environment for the lens, the feed element and the associated electronics, preventing accumulation of ice on the lens. The feed ports typically have an internal rectangular cross-section, as typical in microwave transmission apparatus. The feed ports are arranged so that the ports are aligned about the periphery of lens, thereby allowing a good number of ports to be closely spaced about the periphery of the lens.





FIG. 6

illustrates the operation of a network


211


employing the present invention. A number of network nodes having enclosures


212


-


217


is illustrated with each enclosure, either simultaneously or sequentially, communicating with a number of neighbors in radio line of sight relation using paths


218


-


225


. Paths


226


and


227


which are blocked from being in true line of sight communication by obstacles


228


and


229


, so that nodes


213


and


216


cannot communicate by path


226


, but may communicate via relay of information to other nodes, such as nodes


214


and


215


using paths


219


,


220


and


221


, or alternatively via node


217


using paths


230


and


222


. Similarly nodes


212


and


215


cannot communicate on path


227


because of obstacle


229


, but can communicate using neighbor nodes


214


or


217


, for example, which are in radio line of sight communication. In this case, nodes


212


and


215


could communicate by paths


223


and


232


, or via paths


218


and


225


, as examples. Other paths exist. Communication may be selected via the best available path. It may be seen that route diversity exists in the network with clockwise or counterclockwise paths available. Particular paths are selected by control information in a control channel which update the path availability at the node routing data base. For example, enclosure


213


can communicate directly with enclosure


215


. However, if the direct path is impaired, enclosure


213


can route the communication to node


214


and from there to node


215


. Other paths are available.



Claims
  • 1. A plurality of all weather enclosures for mast mountable microwave radio transceivers in a network, each enclosure comprising,an environmentally protective, mast mountable shroud having a radome projecting from the shroud in line of sight relation to other radomes, a microwave radio transceiver disposed within the shroud, a microwave refractive lens disposed adjacent to the radome, inside of the shroud, and an array of feed ports disposed between the transceiver and the lens in a position communicating microwave energy between the transceiver and the radome through the lens in multiple selected directions, and a plurality of switches selectively connecting feed ports to the transceiver whereby microwave radio energy may be transmitted and received in multiple selected directions.
  • 2. The apparatus of claim 1 wherein the shroud has a brim extending over the radome.
  • 3. The apparatus of claim 1 wherein the shroud has heatsink surfaces within the shroud and cooling fins projecting from an exterior surface of the shroud.
  • 4. The apparatus of claim 1 wherein the shroud has a door in an exterior surface of the shroud giving access to the power supply adjacent to the exterior shroud surface.
  • 5. The apparatus of claim 1 wherein the multiple selected directions span an angle greater than 90 degrees.
  • 6. A plurality of all weather enclosures for outdoor microwave radio transceivers in a network, each enclosure comprising,an environmentally protective, outdoors shroud having a radome, a microwave radio transceiver disposed within the shroud, a ball-shaped microwave refractive lens disposed adjacent to the radome, inside of the shroud, a curved array of feed ports disposed between the transceiver and the lens in a position near a surface of the lens communicating microwave energy between the transceiver and the radome through the lens in multiple selected directions, the curvature of the array following curvature of the lens surface, and a plurality of switches selectively connecting feed ports to the transceiver whereby microwave radio energy may be transmitted and received in multiple selected directions.
  • 7. The apparatus of claim 6 wherein the shroud has a bracket mounting the shroud to a mast, the bracket having angular adjustments for horizontal and vertical angles.
  • 8. An all-weather housing for mast mountable microwave radio transceivers comprising,an exterior shroud protectively shielding an exposed radome in a sealed relationship therewith, the radome having a rounded convex portion pointing in a fixed direction relative to the shroud, the shroud having an extended portion over at least some of the exposed radome and a rearward portion having a mounting bracket attached thereto capable of attachment to a mast, a curved microwave radiation lens located proximate to the radome and within the shroud near an array of feed ports and associated switches capable of directing microwave energy toward and from the lens at different selected angles, and a microwave radio transceiver connected to the switches in a manner selectively directing and receiving microwave energy to and from the feed ports, whereby selectively directed beams containing the microwave energy emerge from and enter the lens in selected directions over an angular range.
  • 9. The apparatus of claim 8 wherein said shroud has a rounded cross-sectional shape.
  • 10. The apparatus of claim 8 wherein the microwave lens comprises a graded index lens.
  • 11. The apparatus of claim 8 wherein the microwave lens comprises a Lunenburg or Morgan lens.
  • 12. The apparatus of claim 8 wherein the shroud encloses an electrical fan circulating air within the shroud.
  • 13. The apparatus of claim 12 further having an electrical heater in proximity to the fan, and a control circuit to operate the heater and the fan to circulate warm air within the radome with sufficient capacity to avoid accumulation of water or ice on the exterior surface of the radome.
  • 14. The apparatus of claim 8 wherein said shroud has a first compartment housing said lens, feed ports and switches and a second compartment housing said transceiver.
  • 15. The apparatus of claim 14 wherein the second compartment envelops the first compartment.
  • 16. The apparatus of claim 14 wherein said compartments are at least partially separated by radio frequency shielding near the base of the radome.
  • 17. The apparatus of claim 8 wherein said shroud has a rearward portion, opposite the radome, having radiative heat sink fins.
  • 18. The apparatus of claim 8 wherein the microwave lens has a ball shape.
  • 19. The apparatus of claim 18 wherein said microwave lens has spaced apart protuberances interlocking with spaced apart sockets of a support frame.
  • 20. The apparatus of claim 19 wherein the spaced apart protuberances are positioned at opposed parts of the ball lens.
  • 21. The apparatus of claim 17 wherein the rearward portion of the shroud has a door mounting a power supply facing toward the radome.
  • 22. The apparatus of claim 21 wherein said door has radiative heat sink fins facing opposite the radome.
  • 23. The apparatus of claim 22 wherein the fins are integral with the shroud.
  • 24. The apparatus of claim 8 wherein a portion of the shroud extends forwardly over the radome forming a protective brim for the radome.
  • 25. The apparatus of claim 8 wherein the array of feed ports direct beams to emerge from the microwave lens spanning an angular range up to 120 degrees.
  • 26. The apparatus of claim 8 wherein the shroud houses a second radio transceiver having a frequency different from said microwave frequency transceiver.
  • 27. The apparatus of claim 26 wherein the shroud has an antenna associated with the second radio transceiver mounted at the bottom of the shroud.
  • 28. The apparatus of claim 17 wherein said mounting bracket is attached to the heat sink part of the shroud.
  • 29. The apparatus of claim 28 wherein the mounting bracket is angularly adjustable across horizontal angles.
  • 30. The apparatus of claim 28 wherein the mounting bracket is angularly adjustable across vertical angles.
  • 31. The apparatus of claim 8 wherein the shroud has a first compartment housing the microwave lens, switches and feed ports array, a second compartment housing electronic components, with the shroud enveloping the first and second compartments.
  • 32. The apparatus of claim 31 wherein the second compartment envelopes the first compartment.
  • 33. The apparatus of claim 28 further comprising a mast supporting said shroud.
  • 34. The Door of claim 21 further comprises a sealed entry for power, data and fiber optic cables to the space below the door.
  • 35. The apparatus of claim 8 wherein the apparatus is one of a plurality of similar microwave radio enclosures in a mesh topology network, each enclosure in radio line-of-sight microwave radio communication with at least another enclosure in said network.
US Referenced Citations (4)
Number Name Date Kind
4397035 Nothnagel et al. Aug 1983 A
6329956 Tateishi et al. Dec 2001 B1
6356247 Hirtzlin et al. Mar 2002 B1
6380904 Ogawa Apr 2002 B1
Foreign Referenced Citations (2)
Number Date Country
WO0025485 May 2000 WO
WO0076088 Dec 2000 WO