BRPI1100091A2 - Floating cells - Google Patents

Abstract

Floating cells. U.S. Patent for a portable, lightweight and highly flexible cellular network cell system for offloading cellular traffic and extending coverage for point events comprising a floating aeronautical cellular platform called a floating cell (1) which communicates with cellular mobile stations (3) via cellular system (2), for example gsm, and with wireless data transmission stations (5) via wireless protocol (4), for example wi-fi or wimax. These stations carry the communication to the cellular mobile network (7). The floating cell in turn is comprised of a housing (8), said housing may contain warps (9), said floating platform further containing support cables (10), paid cargo shipping box (11), radiating devices cellular communication devices (12) and backhaul (13), gimbals (14) for supporting said box or only said radiant devices, mooring cable (15) and ground fixing (16), and may also contain grid containment (17). The floating platform communicates with a data transmission station (18) responsible for making the connection to the network. The paid charge comprises batteries responsible for the operation of the cell over the duration of the event, which may vary from a few hours to a few days, and which may also be stored in a box in the ground responsible for tele-feeding, femto chip cell (or equivalent electronics responsible for processing cellular channels), wireless access point (for wi-fi, wimax or similar communication) and other electronic components responsible for system operation.

Description

"FLOATING CELLS" The present invention patent is intended for a lightweight, high flexibility cellular coverage system using a floating platform (captive balloon). In particular, the aim is to offload traffic during high demand events that recurrently lead to network congestion and also to expand coverage to areas where it does not exist or is precarious.

Radio (cellular) telecommunications networks are designed based on average demand values estimated by the operating area of the companies providing this service. A number of factors contribute to the variation of this demand, such as time of day (existence of peak hours, usually during business hours), seasonal factors and specific events with high concentration of users, for example New Year's Eve, Carnival, shows, events. sports and military parades. For the first problems mentioned, the state of the art shows market-based solutions, such as promotional prices for mobile phone use at specific times and days. For occasional events, actions based on temporary expansion of the network capacity are used. The latter acts directly on the physical infrastructure of the network, adding equipment in high demand regions. The most typical examples of this equipment are the so-called “cells on wheels” (or Cells-on-Wheels COW) or the “cells in a box” (or CIAB for Cell-in-a). -Box), State-of-the-art solutions have great weight and complexity and a visible difficulty in arranging the antennas at a suitable height for the desired coverage. It is also evident that due to its size (trucks or trailers) access to certain events becomes difficult, and due to the space occupied, the authorization to park the vehicle is more expensive.

From the standpoint of embedded electronics, the cells normally present in COW, CIAB or equivalent solutions have equipment very similar to that used in base radio stations. Advances in technology and component miniaturization have led to the ultimate size solution: so-called femto-cells. A single chip today is capable of supporting 64 simultaneous voice users and up to 400 standby smartphone users. All with a power consumption of less than 5 W. Initially designed with the goal of improving mobile phone service indoors, such as homes or workplaces, the solution has also proved to be an excellent alternative for public places such as workstations. subways, shopping malls and also in open places with a large flow of people. The state of the art shows this use being made through antennas positioned at strategic points, ceilings, marquises of buildings, among others, always having a limited field of view. The inventive new solution is to extend the concept for traffic offloading. in rapidly increasing demand events through a lightweight and highly flexible platform designed to provide service over a period of hours to a few days, charging all the power needed to operate the station for that duration. event. Based on each product application case a study will evaluate whether it is best to actually ship the entire battery, or keep the batteries on the ground and tele-feed. The application case will determine the height of the “FLOATING CELL” and the energy required for operation during the event, the latter directly related to the mission time. Thus a variant of the product is to create a ground storage box for batteries to tele-feed to floating equipment.

Due to the idea of platform portability, it is also necessary to present a backhaul system that excludes the need for heavy equipment accompanying the cell. The objective is to transmit to the network the data of communication with the mobile radio equipment, for example via GSM system but which can be extended to any other cellular communication system. Particular hey the transport could be performed via IP (ethemet network). This backhaul will be transmitted via wireless network, for example Wi-Fi or WiMAX. In cases where direct physical connection is easy to apply, for example through fiber optics, backhaul can be done in this way.

One of the problems inherent in the use of captive balloons is its movement, and consequently the embedded electronics, due to the presence of winds, which can sometimes be very strong. Tilting the mooring line can pose a hazard to nearby structures. In addition, moving the antenna can change the irradiation diagram, causing problems in the product's own service. At this point it is very important to develop systems that minimize these effects.

The basic ratios that must be considered when estimating the inclination angle of the cable (a) determine that, at equilibrium, the drag force (D) must be equal to the component of horizontal cable pull (T.cos (o)). ) and the net thrust (already discounting the weight of the equipment) equal to the vertical cable pull component (T.sen (a)). These ratios allow us to state that the higher the net thrust and the lower the drag force, the smaller the deflection angle in the cable. The drag is directly dependent on the square of the wind speed and the drag coefficient of the enclosure. In the first factor it would be possible to estimate it before the events of interest by analyzing wind forecast reports. In case the expected winds are very strong it would be possible to take some preventive measures such as the use of extra cables and the removal of part of the batteries (to increase the net thrust), even if this requires the need to change batteries during the event. The most modifiable point is the drag coefficient. This is directly related to the shape of the balloon, the slimmer (by definition the one that creates the least interference with the flow current lines) the lower the drag coefficient. As an example, changing from a spherically shaped housing to an ellipsoid may decrease the drag coefficient and consequently the drag by up to ten times.

Another aspect is the orientation of the antenna and the change in its radiation profile. If the antenna is rigidly attached to the cable or enclosure, small changes in angle can be expected to have a considerable impact on the ground radiation profile, the higher the ground altitude. One way to keep it always in the same orientation, regardless of winds, is to use so-called gimbals. These are mechanical devices that, through the free rotation of axes, keep the equipment attached to said gimbals always in the same orientation. This device can be used to keep the antenna always in the same position.

In view of these problems and the purpose of overcoming them, a system of rapid expansion of the capacity of a cellular network, object of the present patent, composed of a floating platform (captive balloon), electronic equipment responsible for data and voice transmission, was developed. based on miniaturized cell technology (eg femtocells) and including backhaul communication (for connection to the mobile network via Wi-Fi, WiMAX or similar wireless technology). The platform also includes batteries that do not require tele-power and communication antennas. For backhaul, wireless transmission devices (Wi-Fi, WiMAX or similar) can be installed near existing infrastructure, such as radio base stations located on tops of buildings.

This platform solves the problem of rapidly increasing demand on one-off events by enabling portable access points to be added to the existing cellular network (eg GSM) in public places. This platform is easy to install, requires little space and does not require physical connection to any other equipment or mains (except ground wire). These features make the product highly flexible at the point of installation.

In the field of the use of balloons to support antennas and transmitters, their existence is longstanding. Balloons were used during World War II and on various other occasions for the establishment of radio communications and enemy surveillance. The use of captive balloons is foreseen since 1994 by the Brazilian aeronautical approval regulation (RBHA 101) allowing the support of devices up to 4.5 kg (4.5 m3 of gas, in the case of hydrogen or helium) without specific rules to be applied. or exceed this limit provided that due care is taken under that Regulation. In Brazil a patent of invention privilege claims a product consisting of one of the possible ways to make the disposition and support of said apparatuses. Abroad the use of captive balloons to support transmission devices is also precedent, but not for the purpose of offloading a cellular network or replacing all external electronics (usually located in trailers) with a much more transportable system. and flexible with internal electronics.

The accompanying drawings show the system and its particularities. Fig. 1 shows the system architecture. Fig. 2 shows the floating aeronautical cellular platform, hereinafter referred to as the "FLOATING CELL". The system comprises a floating aeronautical cellular platform (1), hereinafter referred to as the "FLOATING CELL", a plurality of cellular mobile stations (3) and a wireless data transmission station (5) for the backhaul. Said floating aeronautical cellular platform (1) acts as a cell, communicating with said cellular mobile stations (3) through a cellular communication protocol (2), for example GSM, but not restricted thereto. Said floating aeronautical platform (1) is responsible for transporting data to said wireless data transmission station (5) via wireless protocol (4), which may be Wi-Fi, WiMAX or similar communication. . In the particular case where the distance between said floating aeronautical cellular platform (1) and said wireless data transmission station (5) is small, the wireless communication protocol (5) may be replaced by a direct connection. via cable, for example an ethemet network. Said wireless data transmission station (5) is responsible for transporting the data to an IP network (6), in turn said said network transports the data towards the cellular mobile network (7). The housing (8) is made in an aerodynamic shape, resembling an airship or airplane fuselage, or in lenticular shape (resembling a flying saucer). This is done to minimize the drag force generated by the winds, which directly impacts the tilt angle assumed by the mooring line. The possibility is not excluded, however, that the envelope, for simplicity and economy, may be in conventional format (cylindrical or natural balloon shape), however, noting that this would result in a penalty for its stabilization, more susceptible to winds. The enclosure may further contain stabilizing surfaces, said warps (9), responsible for keeping the balloon oriented in the wind direction, maintaining the minimum drag force regardless of changes in wind direction and intensity during operation. Support cables (10) support a box (11) that contains all paid platform load. Said housing (11) may also be connected directly to said housing (8). Outside the box (11) are radiating cellular communication devices (12) and backhaul (13) connected to it. These devices may be attached to a gimbal (14) responsible for keeping the radiating device or the box itself always in the same vertical orientation, allowing constant signal coverage and independent of wind direction and intensity variations. Said radiating devices (12 and 13) may consist of a single antenna integrating the functions. Said support cables (10), which may be connected directly to said housing, are connected to a mooring cable (15), which consists of a sturdy steel cable or other material capable of resisting with adequate safety margin to the stresses. expected, linked in turn to a terrestrial fixation (16). This attachment may be a direct fixed point in the ground, surrounded by a retaining grid (17) supporting said mooring line for deflection angles greater than a previously specified angle, providing protection to the cable and especially to persons. near the attachment point. This attachment can also be a simple solid covering (eg a pipe of resistant material) correctly fixed to the ground. Also attached to the cable is a conductive wire for grounding in the event of an electrical discharge. Said paid charge comprises batteries responsible for the functioning of the cell over the duration of the event, which may vary from a few hours to a few days, femto-cell chip (or equivalent electronics responsible for processing cellular channels), wireless access point ( for Wi-Fi, WiMAX or similar communication) and other electronic components responsible for the operation of the system. In addition, a ground box (18) can be found, where the conditions of the event considered make the energy tele-power more efficient than the shipping of the batteries, in which case the extra cable weight compensates for the removal of the batteries. In this situation the batteries are in said ground box (18), which may also contain an input for external power in case of high duration events.

It is also interesting that the housing (8) is of low opacity material, allowing it to also be used, with the aid of a low consumption internal lamp, for advertising purposes.

Claims (8)

1. “FLOATING CELLS” system characterized by: a) A plurality of cellular mobile stations. b) A cellular mobile network. c) A plurality of wireless data transmission stations. d) A plurality of floating aeronautical cellular platforms, "FLOATING CELLS", where said floating aeronautical cellular platforms communicate with said cellular mobile stations via cellular communication system, for example GSM and where said floating aeronautical cellular platforms communicate said wireless data transmission stations via wireless protocol, for example Wi-Fi or WiMAX. 2. Floating aeronautical cellular platform, or “FLOATING CELL”, characterized by having: a) A housing that stores the gas responsible for generating buoyancy, which may be constructed in aerodynamic shape and contain warping to increase stability. b) A mooring line for making said housing captive to grounded objects also comprising possible data and / or power cables. c) A cellular transmitter (pico cell, femto cell or similar technology). d) A plurality of antennas. e) A wireless backhaul transmitter. f) A box containing electronics responsible for generating power during the mission time and said transmitters. 3. A “FLOATING CELL” as in (2) characterized in that the backhaul transmitter is a Wi-MAX, Wi-Fi or similar voice and data transmission technology. 4. A "FLOATING CELL" as in (2) characterized in that the backhaul transmitter is replaced by a cable connection point for direct connection to said wireless data transmission station. 5. A “FLOATING CELL” system as in (1) characterized by backhaul communication being carried out via cable, for example fiber optics. 6. A “FLOATING CELL” as in (2) where said power generating electronics is fixed to the ground inside a ground box and power transmission is via cable connected from said ground box to said box as in (2) responsible for other electronic equipment. 7. A “FLOATING CELL” as in (2) characterized in that said housing is made for the extra purpose of providing advertising, including: a) Company logo b) Interior light 8. A "FLOATING CELL" as in (2) characterized in that said radiating equipment or said box is held in position by gimbals made of lightweight material, for example carbon fiber.