This application claims the benefit, under 35 U.S.C. §119 of FR Patent Application 1154154, filed 13 May 2011.
The present invention relates to a multibeam antenna system, particularly a multibeam antenna system usable in the context of wireless communications, more particularly in the domestic networks in which the propagation conditions of electromagnetic waves are very penalising.
For emerging applications such as wireless domestic networks, smart networks or similar networks, the use of directive antennas, namely antennas with the faculty of focussing the radiated power in a particular direction of space, proves to be particularly attractive. Indeed, the use of directive antennas can reduce the power of transmitters and significantly limit interferences, the reduction in power of the transmitters is translated by a reduction of costs of equipment and/or increase in the lifetime of batteries and hence the autonomy of mobile equipment or wireless sensors.
However, the laws of physics require a minimum size for antennas, this size being all the greater as the antenna is directive or its operating frequency low. Hence, until now, the use of directive antennas has remained limited to antennas operating at very high frequencies, often at fixed frequencies, and not having size constraints such as radar applications or satellite applications.
However, to increase the capacity and bitrates of wireless systems, the emerging applications such as MIMO systems (for Multiple Input Multiple Output) use multiple antenna techniques. Hence, the grouping of directive antennas into networks is sometimes necessary to ensure point to point coverage in the entire space or on 360°. Moreover, to these more or less agile semi-directive antenna devices, a digital processing unit must be added to control and shape the beams in the directions required by the system. Indeed, the basic principle of a multibeam antenna system lies in the choice of one beam among a row of diverse fixed beams pointing in prioritised and predefined directions. The switching from one beam to another is decided according to, for example, the highest signal-to-noise ratio at reception.
Hence, in terms of integrated function within a multibeam antenna system, this must comprise a beam shaper that generates multiple beams, a listening circuit that is used for determining the beam to use to enable the optimal communication and a switch that is used to select the optimal beam for the reception. Therefore, the solutions currently on the market are complex solutions and, consequently, costly and/or bulky.
The present invention thus proposes a multibeam antenna system that enables a response to the above problems by proposing a multibeam antenna system based on the joint use of a plastic lens and multiple sources.
Moreover, the present invention thus proposes a new compact multibeam antenna solution enabling pattern in different directions of space to be chosen with an extremely simple and non-expensive implementation technology.
The present invention relates to a multibeam antenna system comprising:
According to an embodiment, the cylindrical ring has in cross-section a circular or parallelepipedic shape. The circular ring has a thickness close to λg/4, where λg is the guided wavelength. This allows an optimisation of the thickness of the lens.
Moreover, the material of the lens is chosen from among plastic materials such as polymethylmethacrylate (known under the name PLEXIGLAS® acrylonitrile-butadiene styrene (known under the name ABS). Other materials such as ceramics or magneto-dielectric materials can also be used to produce the lens. The radiating elements, themselves, are chosen from among the monopoles, patches, slots. Moreover, each monopole is associated with a reflector positioned on the external surface of the lens so as to bring the radiation of the source in the direction of the lens.
According to another characteristic of the present invention, the different radiating elements are arranged in a circle surrounding the lens. The distribution of the radiating elements in a circle increases the uniformity, namely the symmetry, of the radiation patterns between each other
Other characteristics and advantages of the present invention will emerge upon reading the following description of an embodiment, this description being made with reference to the drawings attached in the appendix, in which:
As shown in
More generally, any material having a permittivity and/or a permeability different from 1 can be used to produce the lens. In the embodiment of
As shown in
In
According to a characteristic of the present invention, the thickness of the ring forming lens 2 was optimised to be close to λg/4 where λg is the guided wavelength and is equal to
with λ0 the wavelength in a vacuum, ∈r the permittivity and μr the permeability of the material forming the lens.
A description will now be made of the embodiment according to the configuration of
The substrate is a substrate in a known material FR4 formed by a square of length ˜2.75 λ0.
The distance between the centre of a reflective strand 4 and the centre of a radiating element is 0.15 λ0.
The distance between a radiating element 3 and the external wall of the lens 2 is 0.0725 λ0.
The internal diameter of the lens 2 is 0.4 λ0.
The height of a reflective strand 4 is 0.3λ0.
The height of a monopole is 0.25 λ0.
The height of the plastic lens is 0.367 λ0.
As shown in
By using the aforementioned dimensions, different patterns and curves shown in
It is also evident that, in the antenna system of
In
The curves of
The embodiment described above is a simple and low cost embodiment using low cost materials such as a plastic material for the lens, an FR4 type substrate for the substrate and metal strands for the radiating elements and reflective elements. Moreover, the dimensions of the lens, namely the interior and exterior diameters of the ring, the distance between the source and the reflective element, the distance between the wall of the lens as well as the height and position of the lens and the number of sources, make it possible to optimise the directivity and the level of matching in the targeted frequency band.
Number | Date | Country | Kind |
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11 54154 | May 2011 | FR | national |
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Number | Date | Country | |
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20120287005 A1 | Nov 2012 | US |