Patent Publication Number: US-2023146405-A1

Title: Vertically stacked, integratable, multipurpose platform configurable as wireless base stations

Description:
This application claims the benefit of U.S. Provisional Application Ser. No. 63/243,467, filed Sep. 13, 2021 and is a continuation-in-part of U.S. Application Ser. No. 17/337,754, filed Jun. 3, 2021 which is a continuation of U.S. Ser. No. 16/354,971 filed Mar. 15, 2019 which claims the benefit of U.S. Provisional Application Ser. No. 62/643,441 filed Mar. 15, 2018. 
    
    
     TECHNICAL FIELD 
     The present application relates to vertically stacked, integratable, multipurpose platform configurable as wireless base stations and apparatuses, methods, systems, and techniques relating thereto including, but not exclusive to apparatuses, methods, systems, and techniques relating to LTE, 5G wireless or future technologies and edge computing micro-base stations. 
     BACKGROUND 
     Wireless communications infrastructure, networks, and services are progressing toward 5G wireless standards and technologies. As part of this development, wireless base stations may be deployed at the street level utilizing existing infrastructure, such as utility poles or street light structures, or their own dedicated poles or structures to provide LTE or 5G cellular coverage. These deployments require pole space or other mounting space to implement and typically lack battery backup power. Such deployments are also limited in radio frequency (RF) power and capacity to process multiple users, resulting in undesirable coverage limitations. Conventional efforts to compensate for these limitations add antennas and RF equipment making such deployments bulky, wasteful of footprint space, and aesthetically unpleasant. Use of existing infrastructure, such as street lights, requires retrofitting new equipment and/or installing new poles to withstand the additional equipment weight. This is an expensive and time-consuming process, requiring ad hoc solutions to accommodate the variation in existing infrastructure. At the same time, upcoming “smart city” deployments such as interactive kiosks, surveillance cameras and sensors necessitate additional space and resources. Current deployments typically require stand-alone platforms used to convey information via kiosks placed in locations of heavy foot traffic such as community centers, bus or train stations, malls, or other commercial locations and have limited if any radio coverage as the height and connectivity provided by such deployments are limited. There remains a substantial unmet need for the unique apparatuses, methods, and systems disclosed herein. 
     DISCLOSURE OF EXAMPLE EMBODIMENTS 
     For the purposes of clearly, concisely, and exactly describing example embodiments of the present disclosure, the manner, and process of making and using the same, and to enable the practice, making, and use of the same, reference will now be made to certain example embodiments, including those illustrated in the figures, and specific language will be used to describe the same. It shall nevertheless be understood that no limitation of the scope of the invention is thereby created and that the invention includes and protects such alterations, modifications, and further applications of the example embodiments as would occur to one skilled in the art with the benefit of the present disclosure. 
    
    
     
       BRIEF DESCRIPTION OF THE FIGURES 
       A number of example embodiment illustrating certain aspects of vertically stacked, integratable, multipurpose platforms which are configurable as wireless base stations and which may be referred to herein as a tower or towers are illustrated in the figures in which: 
         FIG.  1    is a side sectional view illustrating certain aspects of an example tower in an unloaded or substantially empty state. 
         FIGS.  2 A and  2 B  are perspective views illustrating certain aspects of a support frame of a tower according to the present disclosure at different stages of assembly. 
         FIGS.  3 A and  3 B  are perspective views illustrating certain aspects of a support frame of a tower according to the present disclosure at different stages of assembly. 
         FIG.  4 A  is a top view illustrating certain aspects of a support frame of a tower according to the present disclosure. 
         FIG.  4 B  is a top view illustrating certain aspects of another support frame of a tower according to the present disclosure. 
         FIG.  5 A  is a top view illustrating certain aspects of a support frame of a tower according to the present disclosure. 
         FIG.  5 B  is a top view illustrating certain aspects of another support frame of a tower according to the present disclosure. 
         FIGS.  6 A- 6 E  are several views illustrating certain aspects of example illumination systems useable in connection with a support frame of a tower according to the present disclosure. 
         FIGS.  7  and  7 A  are side sectional views illustrating certain aspects of an anchoring foundation useable in connection with a support frame of a tower according to the present disclosure. 
         FIG.  8    is a side view illustrating certain aspects of a top portion of a support frame of a tower according to the present disclosure. 
         FIGS.  9 A- 9 C  are several views illustrating certain aspects of example panel attachment systems useable in connection with a support frame of a tower according to the present disclosure. 
         FIG.  10 A  is a perspective view of a cabinet enclosure with the cabinet enclosure door open, useable in connection with a support frame of a tower according to the present disclosure. 
         FIG.  10 B  is a top view of the cabinet enclosure of  FIG.  10 A  with the cabinet enclosure door open. 
         FIG.  10 C  is a side view of the cabinet enclosure of  FIG.  10 A  with the cabinet enclosure door closed. 
         FIG.  10 D  is a front view of the cabinet enclosure of  FIG.  10 A  with the cabinet enclosure door open. 
         FIG.  10 E  is a side view of the cabinet enclosure of  FIG.  10 A  with the cabinet enclosure door open. 
         FIG.  10 F  is a front view of the cabinet enclosure of  FIG.  10 A  with the cabinet enclosure door closed. 
         FIG.  11    illustrates an example of printed panels which may be utilized in connection with a support frame of a tower according to the present disclosure. 
         FIG.  12 A  is a perspective view of a tower with a display screen useable in connection with a support frame of a tower according to the present disclosure. 
         FIG.  12 B  is an elevational view of a display screen from  FIG.  12 A . 
         FIG.  12 C  is a side view of the display screen of  FIG.  12 B . 
         FIG.  12 D  is a top view of the display screen of  FIG.  12 B . 
         FIG.  12 E  is a top view of another tower with a display screen. 
         FIGS.  13 A- 13 C  illustrate several cabinet enclosures useable in connection with a support frame of a tower according to the present disclosure. 
         FIG.  13 D  is an exploded perspective view of a cabinet enclosure. 
         FIGS.  14 A- 14 C  illustrate several views of a tower according to the present disclosure at several states of assembly and loading with internal equipment. 
         FIG.  14 D  is an exploded perspective view of the tower. 
         FIG.  15    is a schematic diagram illustrating an example of a micro-mobile edge computing system architecture useable in connection with a tower according to the present disclosure. 
         FIG.  16 A  is a perspective view of a lower support frame according to the present disclosure. 
         FIG.  16 B  is a perspective view of an upper support frame according to the present disclosure. 
         FIG.  16 C  is a fragmentary perspective view of a portion of a panel attachment configuration. 
         FIG.  16 D  is a fragmentary perspective view of a portion of a panel attachment configuration on a vertical column. 
         FIG.  17    is a perspective view illustrating certain aspects of a support frame of a tower according to the present disclosure. 
         FIG.  18    is a top view illustrating certain aspects of a support frame of a tower according to the present disclosure. 
         FIG.  19    is a detailed view of a portion of  FIG.  18   . 
         FIG.  20    is a top view illustrating certain aspects of an example antenna arrangement coupled with a support frame of a tower according to the present disclosure. 
     
    
    
     DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS 
     This application incorporates by reference U.S. Provisional Application Ser. No. 63/243,467, filed Sep. 13, 2021; U.S. Application Ser. No. 17/337,754, filed Jun. 3, 2021; U.S. Application Ser. No. 16/354,971 filed Mar. 15, 2019; and U.S. Provisional Application Ser. No. 62/643,441 filed Mar. 15, 2018. 
     Referring now to the figures and with initial reference to  FIG.  1   , there is illustrated a wireless base station tower  11  (also referred to herein as tower  11 ) in an unloaded or substantially empty state in which the internal electronic equipment and other components that may be contained or housed within the tower  11  are omitted. In the illustrated embodiment, the tower  11  is configured and provided as a freestanding structure mounted on and extending vertically upward from a foundation  120  by a fixation system  70  to a height  130  and extending over a diameter or width  160 . The tower  11  includes a base plate  80  which is affixed to the anchor bolts  100  (e.g., J-bolts or other fasteners) at a spaced-apart location above the upper surface of the foundation. The tower  11  may be freestanding or self-supporting such that the only ground anchoring connections of the support frame are provided via a first plurality of apertures of a base plate  80  which receive the anchor bolts  100 . 
     The height  130  can advantageously be between 20 and 65 feet, but other heights are also encompassed by the invention. 
     As further illustrated in  FIG.  1   , the foundation  120  extends into an underlying ground surface to a depth  140  which is selected to provide sufficient anchoring to securely support the mass of the tower  11  taking into consideration wind and other environmental forces which the tower  11  may be rated to withstand. The depth  140  may vary depending on variables such as the mass, shape, and wind force rating of different forms of the tower  11 . In the illustrated embodiment the foundation  120  is formed of concrete reinforced with a rebar cage  110  and includes J-bolts  100  or other fasteners partially embedded in and extending from the upper surface  199  of the foundation  120 . Leveling nuts  192  can be provided on the bolts  100 . 
     As further shown in  FIGS.  7  and  7 A , one or more telecommunications feeds  194 , electrical power feeds  191 , and electrical grounding rods or conductors  193  may extend from the foundation  120  through the base plate  80  to the interior of the tower  11 . It shall be appreciated that the foundation  120  may be provided in a number of other configurations, forms, and variations providing sufficient anchoring force to accommodate different configurations, forms, and variations of the tower  11 . One or more air inlet apertures  80   a  are provided in the base plate  80  to provide an air intake  80   a  at the bottom of the tower  11  mounted over base plate  80 . 
     As further illustrated in  FIG.  8   , the upper frame section  15  of the tower  11  contains an antenna mounted pole  50  bolted and/or welded to a top plate. The upper frame section  15  may be capped with a top cover assembly  40  including one or more exhaust ports  40   a  to allow air to be drawn in from the air intake at the bottom of the tower  11  and to exit from the upper region of tower  11 . The upper frame section  15  may also include one or more horizontal shelves including one or more vent apertures at a peripheral location of the upper frame horizontal shelves. A GPS antenna  260  may be affixed to the top cover assembly  40  and may be utilized to assist all electronic equipment with timing requirements. 
     With additional reference to  FIGS.  1 ,  2 A,  2 B,  3 A,  3 B, and  16   , the tower  11  includes a support frame  12  comprising a lower frame section  13 , at least one intermediate frame section  14  positioned vertically above and supported by the lower frame section  13 , and an upper frame section  15  positioned vertically above and supported by the at least one intermediate frame section  14 . The lower frame section  13  may define one or more lower structure-free interior compartments horizontally spanning the lower frame section  13 . In the illustrated example, the lower frame section  13  defines two lower structure-free interior compartments  23   a ,  23   b  horizontally spanning the lower frame section  13 . In other embodiments, the lower frame section  13  may be configured to define a single lower structure-free interior compartments, or more than two lower structure-free interior compartments. 
     In the illustrated embodiment, the lower frame section  13  comprises a frame scaffolding  10  including a plurality of vertical columns  33  and a plurality of horizontal beams  43  coupled with and extending between respective ones of the plurality of vertical columns  33 . A plurality of horizontal shelves  190  are supported by respective sets of one or more of the plurality of horizontal beams  43  and extend between the plurality of vertical columns  33 . The structure-free interior compartments  23   a ,  23   b  are bordered by and extend horizontally between the plurality of vertical columns  33  and vertically between opposing sets of the plurality of horizontal beams  43 . The plurality of horizontal shelves  190  and the plurality of horizontal beams  43  may be selectably positionable at a plurality of vertical fixation locations along the height of the plurality of vertical columns  33 . 
     The lower frame section comprises a base plate  80  supporting the plurality of vertical columns  33 , the plurality of horizontal beams  43 , and the plurality of horizontal shelves  190 . As further illustrated in  FIGS.  7 , and  7 A , the base plate  80  can include a plurality of ventilation apertures  80   a  which register with at least the lowest most vents  115 ,  116  of the shelves, mounting holes  100   a  sized and positioned to receive ground anchor bolts, and one or more second apertures sized and positioned to receive one or both of an electrical power cable or electrical feed  191  and a network communication line or telecom feed  194 . One or more gussets  195  may be provided to reinforce the attachment between the base plate  80  and vertically extending structures of the tower  11 . 
     The tower  11  can be configured such that the baseplate  80  functions as the lowermost shelf, or can be configured such that a lowermost shelf  190 ,  190   a  overlies the baseplate  80 . 
     The intermediate frame section  14  defines at least one intermediate structure-free interior compartment. In the illustrated example, the intermediate frame section  14  defines two lower structure-free interior compartments  24   a ,  24   b  horizontally spanning the intermediate frame section  14 . In other embodiments, the intermediate frame section  14  may be configured to define a single intermediate structure-free interior compartment, or more than two intermediate structure-free interior compartments. In the illustrated example, the intermediate frame section  14  is provided as a single intermediate frame section. In other embodiments, the intermediate frame section  14  may comprise two or more intermediate frame sections which may be coupled with one another. 
     In the illustrated embodiment, the intermediate frame section  14  comprises a frame scaffolding including a plurality of vertical columns  34  and a plurality of horizontal beams  44  coupled with and extending between respective ones of the plurality of vertical columns  34 . A plurality of horizontal shelves  190  are supported by respective sets of one or more of the plurality of horizontal beams  44  and extend between the plurality of vertical columns  34 . The structure-free interior compartments  24   a ,  24   b  are bordered by and extend horizontally between the plurality of vertical columns  34  and vertically between opposing sets of the plurality of horizontal beams  44 . The plurality of horizontal shelves  190  and the plurality of horizontal beams  44  may be selectably positionable at a plurality of vertical fixation locations along the height of the plurality of vertical columns  34 . It shall also be appreciated that other embodiments contemplate different numbers, positioning, alignments, and orientations of frame scaffolding members. 
     As further illustrated in  FIGS.  16 A- 16 D , panel retaining members  33 ′,  43 ′ may be coupled with the vertical columns  33 ,  34 . Panel retaining members  43 ′,  44 ′ may be coupled with the horizontal beams  43 ,  44  by fasteners  111 . Fasteners  111  may be provided in a form compatible with or requiring use of a keyed installation to provide a security barrier against removal of the exterior panels  240 ,  241 . Exterior panels  240 ,  241  may be disposed therebetween and may be retained by panel retaining members  33 ′,  43 ′ and panel retaining members  43 ′,  44 ′ by fasteners  111 . A seal or gasket  242  may be provided adjacent the exterior panels  240 ,  241 . The fasteners  111  may be provided as keyed fasteners, such as keyed bolts or keyed screws, to provide a security locking mechanism providing tamper resistance and for the interior of the tower  11 . It shall be appreciated that the embodiment of  FIGS.  16 A- 16 D  provides one example of attachment or fixation of exterior panels with a tower such as the tower  11 . Other embodiment may include one or more of a plurality of solid exterior panels being coupled with the support frame by a hinge accommodating opening to provide access to at least one of the lower structure-free interior compartments and the intermediate structure-free interior compartments. 
     In the illustrated example, the plurality of vertical columns  33  comprises four vertical columns arranged such that an inward facing surface of each of the four vertical columns intersects a respective corner of a rectangle with sides extending between respective pairs of the four vertical columns. It shall also be appreciated that other embodiments contemplate different numbers, positioning, alignments, and orientations of frame scaffolding members. 
     As illustrated in  FIGS.  4 A and  5 A , the horizontal shelves may be generally square or rectangular horizontal shelves  190  and the plurality of vertical columns  33 ,  34  may be aligned, oriented and positioned to maximize or increase the internal space within the frame scaffolding  10 . For example, the plurality of vertical columns  33 ,  34  may be oriented such that a first major surface of the each of the plurality of vertical columns  33 ,  34  is oriented to face a first major surface of another of the plurality of vertical columns  33 ,  34  and a second major surface of the each of the plurality of vertical columns  33 ,  34  is oriented to face a second major surface of another of the plurality of vertical columns  33 ,  34 . Furthermore, the plurality of vertical columns  33 ,  34  may be oriented such that a first of two surfaces of a first one of the first plurality of vertical columns is parallel with and face a surface of a second one of the first plurality of vertical columns and a second of the two surfaces of the first one of the first plurality of vertical columns is parallel with and face a surface of a second one of the first plurality of vertical columns. A plurality of generally flat exterior panels  240  may extend between opposing major faces of pairs of the plurality of vertical columns  33 ,  34 . Vent apertures  115  may be provided inside and proximate the boundary or border provided by the panels  240 . 
     As illustrated in  FIGS.  4 B and  5 B , the horizontal shelves may also be generally circular or rounded horizontal shelves  190   a  and the plurality of vertical columns  33 ,  34  may be aligned, oriented and positioned to maximize or increase the internal space within the frame scaffolding  10 . For example, the plurality of vertical columns  33 ,  34  may be oriented such that a first major surface of the each of the plurality of vertical columns  33 ,  34  is oriented to face a first major surface of another of the plurality of vertical columns  33 ,  34  positioned generally across the diameter of the generally circular or rounded horizontal shelves  190   a . Furthermore, the plurality of vertical columns  33 ,  34  may be oriented such that the inward facing surface of a first one of the first plurality of vertical columns is parallel with and faces the inward facing surface of a second one of the first plurality of vertical columns, and the inward facing surface of a third one of the first plurality of vertical columns is parallel with and faces the inward facing surface of a fourth one of the first plurality of vertical columns. A plurality of curved exterior panels  241  may extend between opposing major faces of pairs of the plurality of vertical columns  33 ,  34 . Vent apertures  115  may be provided inside and proximate the boundary or border provided by the panels  241 . 
     The illustrated embodiments provide examples of a lower frame section  13  comprising a polygonal frame module including a first plurality of open-aperture faces  30  providing unobstructed access to a lower structure-free interior compartment which may be selectably and removably covered with exterior panels and an intermediate frame section comprising a polygonal frame module including a plurality of open-aperture faces providing unobstructed access to an intermediate structure-free interior compartment which may be selectably and removably covered with exterior panels. Such access may be provided around substantially the entire exterior of the lower frame section  13  and the intermediate frame section  14 , for example, from each of four exterior faces of the tower  11  in the illustrated embodiment. It shall also be appreciated that other embodiments contemplate different numbers, positioning, alignments, and orientations of frame scaffolding members and different resulting in different numbers, positioning, alignments, and orientations of open-aperture faces providing unobstructed access to an intermediate structure-free interior compartment which may be selectably and removably covered with exterior panels. 
     The lower frame section  13  and the intermediate frame section  14  may be provided, coupled, or fastened to one another in a number of manners. For example, the lower frame section  13  and the intermediate frame section  14  may each comprise a first polygonal frame module and at least one second polygonal frame module may be provided as discrete structures configured to selectably and reversibly fasten and unfasten from one another. Alternatively, each of the lower frame section  13  and the intermediate frame section  14  may be provided as a single or common discrete structure. Furthermore, the lower frame section  13  and the intermediate frame section  14  may respectively comprise a first polygonal frame module and a second polygonal frame module provided as discrete structures configured to selectably and reversibly fasten and unfasten from one another. Alternatively, the lower frame section  13  and the intermediate frame section  14  may be provided as a single or common discrete structure. In some embodiments a plurality of intermediate frame sections  14  may be provided. 
     As illustrated in  FIG.  2 A , the lower frame section and the intermediate frame section may respectively comprise a female mating structure  16   a  and a male mating structure  16   b  as part of facing ends of the vertical columns. In some embodiment, the lower frame section and the intermediate frame section may be welded to one another. In some embodiment, the lower frame section and the intermediate frame section may be coupled with one another by strength-bearing screws. In some embodiments, a combination of two or more of the foregoing attachment, coupling, or fixation techniques may be used. 
     With additional reference to  FIGS.  3 A and  3 B and  17 - 20   , the upper frame section  15  includes an upper frame horizontal shelf  55 , and a central post  50  (also referred to as antenna mounting pole  50 ) coupled with the upper frame horizontal shelf  55  by a lower flange  52  and extending vertically upward from the upper frame horizontal shelf  55 . A top cover assembly  40  is coupled with the central post  50  by an upper flange  51 . One or more peripheral members extend between the upper frame horizontal shelf  55  and the top cover assembly  40 . The upper frame section  15  defines an upper structure-free interior region  25  extending between the central post  50  and the one or more peripheral members. 
     The one or more peripheral members may be provided in a number of forms. As illustrated in  FIG.  3 A , the one or more peripheral members may comprise a plurality of vertically extending members  53  and a plurality of exterior panels  200  coupled therewith. The panels can be of LEXAN material, but other panel materials are encompassed by the invention. In the illustrated example, the upper frame horizontal shelf  55 , the top cover assembly  40 , the plurality of vertically extending members  53 , and the plurality of exterior panels  200  are provided and configured in a generally circular or round form analogous to the corresponding generally circular or round forms of lower frame section  13  and the intermediated frame section  14  illustrated and described in connection with  FIGS.  4  and  5   . In other embodiments, the upper frame horizontal shelf  55 , the top cover assembly  40 , the plurality of vertically extending members  53 , and the plurality of exterior panels  200  are provided and configured in a generally square or rectangular form analogous to the corresponding generally square or rectangular forms of lower frame section  13  and the intermediated frame section  14  illustrated and described in connection with  FIGS.  4  and  5   . Similarly, the alignment, orientation, and positioning of the plurality of vertically extending members  53  may correspond to the generally circular or round form or the generally square or rectangular forms of lower frame section  13  and the intermediated frame section  14  illustrated and described in connection with  FIGS.  4  and  5     
     As illustrated in  FIG.  3 B  and  FIGS.  17 - 20   , the one or more peripheral members may comprise a first peripheral member fixedly disposed intermediate the upper frame horizontal shelf and the top cover, for example, a first exterior panel  202  or an exterior panel with another shape or span. The one or more peripheral members may further comprise a second peripheral member removably disposed intermediate the upper frame horizontal shelf and the top cover, for example, a second exterior panel  203 . In the illustrated example, the first exterior panel  202  extends about central post  50  over a range of 270 degrees +/- 15 degrees and the second exterior panel  203  member extends about central post  50  over a range of 90 degrees +/- 15 degrees. These ranges are preferred to balance the mass of the second exterior panel  203  while with accessibility to upper structure-free interior region  25 . It shall be appreciated that other angle ranges may be selected depending on the mass and accessibility requirements of a given embodiment. 
     As illustrated in  FIGS.  9 A -  9 C , the exterior panels  200  may be secured in place by retention members  60  which are coupled with vertical members  53  by fasteners  211 . Alternatively, as illustrated in  FIG.  19   , the first exterior panel  202  and the second exterior panel  203  may include respective mating junction portions  202   j ,  203   j  which may be provided as milled portions with a reduced radial thickness. The mating junction portions  202   j ,  203   j  may be coupled to one another by one or more cover members  205  and one or more fasteners  206 . 
     As illustrated in  FIG.  18   , the upper frame section  15  includes a sleeve  350  positioned about and selectably rotatable relative to the central post  50 . In the illustrated example, the sleeve  350  is configured as a tubular member or a cylinder with a hollow interior. The sleeve  350  may include or be coupled with a mounting ring  351  which provides a region of increased diameter that may be received by fasteners  352 ,  353  to fixedly couple one or more antennas  66  with the sleeve  350  such that the one or more antennas  66  and rotatable with the sleeve  350  relative to the central post  50 . 
     The one or more antennas  66  may comprise at least two antennas arranged in a sectorized relationship. As illustrated in  FIG.  20   , for example, the one or more antennas  66  comprise three antennas  66 A,  66 B,  66 C arranged in a triangularly sectorized relationship such that the antennas are oriented at respective directions offset by angles A1, A2, A2 which may be equal to 120 degrees. 
     One or more fasteners (not illustrated) may be coupled with the sleeve  350  and adjustable between a first configuration wherein the sleeve is rotatable relative to the central post and a second configuration wherein the sleeve is rotationally fixed relative to the central post. The one or more fasteners comprise, for example, one or more set screws, pins, clamps, cams, or combinations thereof. 
     It shall be appreciated that the illustrated embodiments are examples in which at least one RF antenna  66 ,  66 A- 66 C is contained in and occupies a portion of an upper structure-free interior region  25  as well as examples of embodiments wherein the at least one RF antenna  66 ,  66 A- 66 C comprises the only radiating antenna. 
     With reference to  FIGS.  6 A- 6 E , there are illustrated several examples of LED lighting placement for illumination of the tower  11 . As shown in  FIGS.  6 A and  6 B , LEDs  213  may be placed on horizontal shelves  190   a  at locations intermediate the vent apertures and vertical frame members of a given level of the tower  11 . As shown in  FIG.  6 C , LEDs  213  may be placed on vertical frame members, such as  33 ,  34 , of the tower  11 . As shown in  FIG.  6 D , LEDs  213  may be placed on or proximate a baffle which is configured to cover a portion of the tower  11 . As shown in  FIG.  6 E , LEDs  213  may be placed on a mesh  217  which may be extended or suspended across the structure-free interior portion proximate the external panels. The example positioning of LEDs  213  may be effective to illuminate exterior panels provided with preprinted graphics and/or text as shown in  FIG.  11   . It shall be appreciated that such illumination systems may be utilized in connection with any of exterior panels  200 ,  202 ,  203 ,  240 ,  241 , or other exterior panels herein. It shall likewise be appreciated that the various features described in connection with any one of exterior panels  200 ,  202 ,  203 ,  240 ,  241 , or other exterior panels herein may likewise apply, mutatis mutandis, to any one of exterior panels  200 ,  202 ,  203 ,  240 ,  241 , or other exterior panels, 
     With additional reference to  FIGS.  10  -  14   , the tower  11  may be configured to house or contain a plurality of electronic subsystems. As shown in  FIGS.  10 ,  13 , and  14   , and one or more environmentally sealed enclosures  180  (e.g., a NEMA enclosure) may be provided for insertion into structure-free interior compartments. The environmentally sealed enclosures  180  may include access doors  182  which may be secured by lock and key. The environmentally sealed enclosures  180  may be mounted on extensible slides  181 . One or more of the environmentally sealed enclosures  180  may include power electronics  184  such as circuit breakers  184   a , rectifiers  184   b , fuse panels  184   c , power strips  184   d , power buses  184   e , fiber-optic multiplexers  184   f , overvoltage protectors  184   g  or other electronics. One or more of the environmentally sealed enclosures  180  may include battery systems  183  providing backup power. One or more of the environmentally sealed enclosures  180  may include a heat exchanger  185  disposed on access doors  182  as well sealing systems including gaskets  188  providing sealing of doors  182  with the environmentally sealed enclosures  180 . One or more of the environmentally sealed enclosures  180  may also include telecommunications equipment  184 . Other electronics such as antenna array 6, and amplifier or receiver system 7 may also be provided and housed or contained by the tower  11 . In some embodiments, one or more weather-hardened electronics units (e.g., water-proof or water-resistant, freeze-thaw-proof or freeze-thaw resistant, humidity-proof or humidity resistant) may be utilized in addition to or as an alternative to environmentally sealed enclosures. One or more knock outs  186 ,  187  can be provided for cable feed as needed. 
     As shown in  FIG.  12   , one or more display screens  210  may be provided and exposed to the exterior of the tower  11 . For example, one or more of the plurality of intermediate frame sections  14  includes a plurality of user interface screens  210 , at least one of the plurality of user interface screens being visible from any position about the support frame. 
     With additional reference to  FIG.  15   , the one or more of the plurality of intermediate frame sections may include a computing system  301  configured and operable as an edge network computing system, in addition to or an alternative to the computing systems configured and operable as a mobile network cell. In some embodiments, at least one of the plurality of intermediate frame sections includes a computing system configured and operable as an edge network computing system, and at least one of the plurality of intermediate frame sections includes a computing system configured and operable as a mobile network cell comprise the same computing system. In some embodiments, at least one of the plurality of intermediate frame sections includes a computing system configured and operable as an edge network computing system and the at least one of the plurality of intermediate frame sections includes a computing system configured and operable as a mobile network cell comprise separate computing systems. Thus, it shall be appreciated that multiple instances of the tower  11  may be utilized in a telecommunications system wherein one or more of the towers  11  are configured to provide an edge computing functionality as well as cellular or mobile network functionality, and one or more of the towers  11  may be configured to provide as cellular or mobile network functionality. Furthermore, the towers  11  may be integrated into a telecommunications system including other small cell and macro cell sites. 
     From the description of the illustrated embodiments, it shall be appreciated that the apparatuses, methods, and systems according to the present disclosure provide for integration and improvement of multiple functionalities, including cellular or mobile communication infrastructure, edge computing, and/or interactive information kiosks. Some such embodiments are suitable for implementation at street level and in areas of high foot traffic. Some such embodiments provide greater connectivity as they are closer to the public thus reducing latency as they are connected with direct internet access, for example, via underground fiber cables. It shall be further appreciated that apparatuses, methods, and systems according to the present disclosure may be utilized to house a number of cell site elements in close proximity to the edge of the network providing an improved system which merges these functions into a single platform without the requirement to replace or overhaul currently deployed appliances or systems. It shall be further appreciated that apparatuses, methods, and systems according to the present disclosure may provide aesthetically pleasing communication infrastructure suitable for downtown areas, historical districts, neighborhoods and other venues where structures deployed must blend into the environment deployed as to match the surroundings. 
     According to some example embodiments, a tower including an aggregation point housed on or within the tower may be provided. The tower can incorporate cellular radios, cellular edge network connectivity, environmental and other sensors, Wi-Fi access points, LCD interactive screens, surveillance cameras, etc. Such towers may be used to replace separate LTE, 5G and smart city solutions with a singular integrated unit. Such towers may be used to provide a multifaceted apparatus which establishes the fundamental elements of a mobile communications network node enhanced with smart city features. For example, as a mobile communications network carriers can utilize a variety of cellular technology solutions such as macro, mini, micro, small cell equipment with antennas mounted at, or near, the highest point of the tower through which a cellular and Wi-Fi signal may be maintained for voice and data for longer distances with the enhancement of power backup and data capacity. Additionally, the mobile communications network can be coupled with smart city applications allowing for cellular and Wi-Fi communications in a variety of ways including, but not limited to, Internet access, phone calls, security monitoring, urban way-finding, providing environmental sensor information to the city’s utilities, and other smart city applications. 
     According to some example embodiments, a tower may comprise modular housing units of varying sizes fitted into the space created by a modular frame architecture and methodology. The tower may be of a modular construction allow for additional housing units to be added or subtracted to increase or decrease the height of the tower based on the capacity requirements and services sought. The tower may be configured to allow for the increase or decrease of the footprint of the equipment mounted on the structure with a simple increase or decrease of the size of the structure supporting poles. 
     According to some example embodiments, a tower can receive and house cellular carrier equipment at a vertical level designated with specific technical functionality, within a housing unit, based on the type of cellular node deployed at the specific location (e.g. macro, micro, mini, small cell, etc.). Some such forms allow for the deployment of environmentally controlled and secured NEMA enclosures in the event a cellular carrier would like to increase capacity by upgrading their equipment to configurations similar to the traditional macro site deployments or increase the power from a small cell to a medium cell power and larger antennas thus increasing the coverage area served. Upper compartments containing radiating elements such as antennas can be varied in size based on the frequency and length of the antenna radiating elements. 
     According to some example embodiments, a tower can be configured in a multiplicity of methods and architectures to serve as an edge networking facility for a cellular network. Some or all space inside the tower could be converted to appropriately include Radio radiating elements, baseband radio systems, and/or data networking and edge processing equipment. In some forms, three of the aforementioned housing units can be substantially identical in dimensions and can be arranged in any order. An interactive kiosk could be self-operational or dependent on computer elements within the tower or the integrated LCD structure. Monitoring functions for radio and all associated equipment can also be accomplished locally or operated remotely. As a result, the tower could be built vertically in a modular building block fashion allowing for space availability to increase or decrease. 
     According to some example embodiments, a tower can include multiple housing units or levels and each of the housing units or levels can be fitted with removable side panels providing 360-degree access to the equipment mounted on the shelf (level). In some forms, one or more of the side panels can be removed or otherwise opened to allow for access from all sides, used to assist in quick installations and maintenance instances. One or more side panels, front and/or the back panels can be replaced by LCD display screen(s). It is also possible to install LCD or similar displays on all four sides of the tower to provide guidance and information to foot or vehicular traffic. 
     According to some example embodiments, a self-standing tower may be mounted into a cement base built to the structure’s diameter or size footprint. In various forms, square, oval, rectangular, or round designs can be deployed with the same support frame of four vertical members. 
     According to some example embodiments, a tower may include cellular and Wi-Fi antennas mounted at the highest point of a tower, allowing for improved signal propagation and fewer obstructions of line-of-sight. The tower may be configured to have a greater height than other potential installation sites such as existing street pole or utility pole installations and may allow for added range and coverage. The tower can accommodate connections such as commercial power or fiber-optics fitted from beneath the tower. All power and fiber can be trenched underground to each location and would run throughout the tower itself. 
     According to some example embodiments, a wireless base station may include a combination of two or more of cellular network equipment, edge computing equipment, an interactive kiosk, surveillance cameras, Wi-Fi access point, fired gun detectors, and environmental sensors in a single platform, and/or a tower. 
     In some embodiments, a multi-purpose tower may be integrated with an interactive screen, may provide an aggregation node to direct and accept traffic to specified end points within the tower or to outside resources; may provide an enclosure containing components supporting a multi-functional purpose; may provide an enclosure with removable access panels at every direction; may provide access to the interactive screen components; may be configured with an internal pole at the top level of the platform or any other level to solidify the mounting of electronic components or antennas and aid in the structural integrity of the tower; may be coupled with commercial power, fiber optics connections and proposed distribution running through the space provided within the interior of the tower; may include a macro/mini/micro/small cell antenna on the top section conforming to existing small cell/micro/mini/Macro products; may provide a macro/mini/micro/small cell functionality with a Wi-Fi access point via a managed switch residing inside the platform; may provide network a macro/mini/micro/small cell with a fiber optics circuit via a managed switch within the platform; or may provide a combination of two or more of the foregoing features. 
     In some embodiments, a multi-purpose tower may network a macro/mini/micro/small cell with a point-to-point radio via a managed switch within the platform, may network a macro/mini/micro/small cell with a surveillance camera via a managed switch residing inside the platform; may network a macro/mini/micro/small cell with smart city sensors via a managed switch within the platform; may network the Wi-Fi access point with a fiber optics circuit via a managed switch residing inside the platform; may network the Wi-Fi access point with a fast Ethernet network via a managed switch residing inside the platform; may network the Wi-Fi access point with a surveillance camera via a managed switch residing inside the platform; may network the Wi-Fi access point with a Point-to-Point radio via a managed switch residing inside the platform; may network the environmental sensors with a fiber optics circuit via a managed switch residing inside the platform; may network the environmental sensors with a fast Ethernet network via a managed switch residing inside the tower platform; may network environmental sensors with a Point-to-Point radio via a managed switch residing inside the tower platform; may network all smart node elements via a managed switch within the tower platform; or may provide a combination of two or more of the foregoing features. The networking protocol or techniques may use currently available VLAN or OSPF techniques or future networking protocol methods. 
     In some embodiments, a multi-purpose tower may direct local network traffic into the fiber optics circuit originating from a surveillance camera and directing traffic via a small cell for monitoring; may direct network traffic into a fast Ethernet network originating from a surveillance camera and directing traffic via the small cell for monitoring; may direct network traffic into the Point-to-Point microwave network originating from a surveillance camera and directing traffic via the small cell for monitoring, utilizing a managed switch within the tower platform; may direct network traffic into the small cell originating from environmental sensor data via a managed switch within the tower platform; may direct local network traffic into the Wi-Fi network originating from environmental sensor data via a managed switch within the tower platform; may direct local network traffic into the Point-to-Point microwave network originating from environmental sensor data via a managed switch within the tower platform; or may provide a combination of two or more of the foregoing features. 
     In some embodiments, a multi-purpose tower may comprise modular or segmented housing units that can be stacked on top of one another in the creation of a singular structure; may be environmentally controlled; may include a structural skeletal frame or scaffolding enclosed by exterior panels; may include modular or segmented housing units securely connected to one another in a stacked arrangement; may include modular or segmented housing units can be added or subtracted to the structure as necessary; may include modular or segmented housing units can be added or subtracted to accommodate equipment needs; may be deployed as a resource in two or more configurations; or may provide a combination of two or more of the foregoing features. 
     Some embodiments provide a multi-purpose tower that is modular and configurable to the needs of the wireless carriers allows the platform to be configured in a multiplicity of configurations before or after initial deployment. For example, the tower can be converted from containing radiating elements like antennas to a smart tower containing only networking, edge computing and radio elements. 
     While example embodiments of the disclosure have been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only certain example embodiments have been shown and described and that all changes and modifications that come within the spirit of the claimed inventions are desired to be protected. It should be understood that while the use of words such as preferable, preferably, preferred or more preferred utilized in the description above indicates that the feature so described may be more desirable, it nonetheless may not be necessary and embodiments lacking the same may be contemplated as within the scope of the invention, the scope being defined by the claims that follow. In reading the claims, it is intended that when words such as “a,” “an,” “at least one,” or “at least one portion” are used there is no intention to limit the claim to only one item unless specifically stated to the contrary in the claim. When the language “at least a portion” and/or “a portion” is used the item can include a portion and/or the entire item unless specifically stated to the contrary.