This application claims the priority under 35 U.S.C. § 119 of Romania application no. A202000575, filed on 11 Sep. 2020, the contents of which are incorporated by reference herein.
The present specification relates to a wireless communication system and method.
Modern wireless and wireline communication standards rely on use of higher frequency (mmWave) bands which are prone to high amounts of path and barrier losses. As a result, techniques to improve the link budget are required.
Existing mmWave systems use physically small antenna arrays to balance (array) antenna gain, device portability and cost. Antenna arrays can support beamforming to direct energy between receiver and transmitter devices, but the beam widths are generally still wide and a lot of energy can be lost in transmission.
In known Fixed Wireless Access systems, the client is often located near a barrier (e.g. behind a wall and/or window) inside the customer premises. In traditional systems, this barrier can impose losses and can be decremental to the link performance. Moreover, an indoor receive antenna may not allow Line Of Sight communications with the base station, thus causing even more power loss.
Aspects of the present disclosure are set out in the accompanying independent and dependent claims. Combinations of features from the dependent claims may be combined with features of the independent claims as appropriate and not merely as explicitly set out in the claims.
According to an aspect of the present disclosure, there is provided a wireless communication system comprising:
user equipment comprising a receive antenna for receiving mmWave signals from a base station transmitter; and
a barrier configured to focus electromagnetic radiation carrying said mmWave signals onto the receive antenna of the user equipment.
According to another aspect of the present disclosure, there is provided a wireless communication method comprising:
providing user equipment comprising a receive antenna;
providing a barrier configured to focus electromagnetic radiation carrying mmWave signals onto the receive antenna of the user equipment; and
receiving mmWave signals at the user equipment by using the barrier to focus electromagnetic radiation carrying the mmWave signals onto the receive antenna of the user equipment, wherein the electromagnetic radiation carrying the mmWave signals is transmitted by a base station.
The barrier may be a window for a building. The use of a window in this way can provide a convenient platform for providing means for focusing the electromagnetic radiation carrying the mmWave signals onto the receive antenna of the user equipment. The window may be a conventional window that has been configured aftermarket to provide the focusing function, or may alternatively be pre-configured to include features for providing the focusing function at the time that it is sold.
The barrier may include an array of elements. Each element may be configured to refract the electromagnetic radiation carrying the mmWave signals by a respective angle, for collectively focusing the electromagnetic radiation carrying the mmWave signals onto the receive antenna of the user equipment. The array may be a two dimensional array. The array may be a regular array (e.g. a rectangular, square, oblong or hexagonal array).
At least some of the elements may be located on a surface of the window. The elements may be applied to a conventional window pane after market, or the window (or the glass pane thereof) may be provided already with the array of elements at the time it is sold.
At least some of the elements may be passive elements.
At least some of the elements may be active elements. This can allow for tuning of the focusing effect, e.g. for compatibility with the location of the receive antenna of the user equipment and/or the interior space of the building in which it is located. In some embodiments, the active elements may include a varactor for tuning a refraction angle applied by each active element to the electromagnetic radiation carrying the mmWave signals.
A surface area of the barrier may be larger than a surface area of the receive antenna of the user equipment. This can allow the effective aperture of the system, for receiving the electromagnetic radiation carrying the mmWave signals to be increased compared to simple reception of the electromagnetic radiation carrying the mmWave signals at the receive antenna of the user equipment absent the barrier.
The user equipment may be a fixed wireless access modem.
The user equipment may be a mobile communications device such as a mobile telephone, tablet or watch.
The wireless communication system may further include the base station.
Embodiments of this disclosure will be described hereinafter, by way of example only, with reference to the accompanying drawings in which like reference signs relate to like elements and in which:
Embodiments of this disclosure are described in the following with reference to the accompanying drawings.
The transmitter node 4 may be a base station. The base station may operate in accordance with the 5G telecommunications standard.
The receiver node 2 may comprise user equipment installed or located in a customer premises. The premises may be domestic or commercial. The receiver node 2 may operate in accordance with the 5G telecommunications standard. The receiver node 2 may be configured to receive signals from the transmitter node 4 and relay them locally (e.g. to other devices located within the customer premises) using a LAN or WLAN. The receiver node 2 may comprise a fixed receiver (e.g. a fixed wireless access modem) installed in the customer premises, or may alternatively comprise a mobile client device such as a mobile telephone.
The receiver node 2 may comprise a receive antenna, as will be described in more detail below. The receiver node 2 may also have transmit functionality (e.g. using the receive antenna as a transmit antenna). For brevity, the present disclosure will be describe the operation of the Fixed Wireless Access system in the context of signals transmitted by the transmitter node 4 and received by the receiver node 4, but it will be appreciated that the principles described herein may also apply to signals transmitted by the receiver node 4 and received by the transmitter node 4.
The barrier 10 may typically comprise some part of the structure (building) of the customer premises. In the embodiments described herein, the barrier 10 comprises a window, although it will be appreciated that the barrier 10 may comprise some other part of the building (e.g. door, wall etc.).
As can be seen in
As shown in
The elements 20 may be arranged in a regular array, such as a rectangular (e.g. square or oblong) array. The elements 20 may be applied to a surface of the pane 30 or panes 30. In some examples, the window may be sold with the elements 20 in situ. However, it is also envisaged that the elements 20 may be applied to an existing barrier 10 (e.g. glass window pane 30). The elements 20 may be considered to form a meta surface for focusing the electromagnetic radiation 16 transmitted by the transmitter node 4 onto the receive antenna of the receiver node 2. Examples of suitable meta-surfaces that may be used are described at:
The transmit antenna of the transmitter node 4 may be considered to be made up of a plurality of transmit antenna elements 14. Similarly, the receive antenna of the receiver node 2 may be considered to be made up of a plurality of receive antenna elements 12.
In order to configure the Fixed Wireless Access system for correct focusing of the electromagnetic radiation 16 onto the receive antenna of the receiver node 2, the spatial relationship between the barrier 10 and the receive antenna of the receiver node 2 must be established. This may be achieved in a number of ways. In one example, the focus point provided by the elements 20 may be known, and the receive antenna of the receiver node 2 may be placed at or near to this point within the customer premises. In another example, the location of the focus point may be configurable within a range of locations relative to the location of the barrier 10 including the elements 20. This may allow the user some flexibility in the placement of the receive antenna of the receiver node 2.
In the arrangement of
For these assumptions to hold true, the following far-field conditions need to apply (where h is the distance between the distance between the window and the receive antenna array of the receiver node 2):
These assumptions do hold true if, for example, λ=1 cm, N=64, h>>8 cm (these example values are consistent with a typical mmWave system).
In accordance with embodiments of this disclosure, the window and the elements 20 thereof act as a series of refractive elements, each element being configured to re-direct the electromagnetic radiation carrying the mmWave signals onto the receive antenna of the receiver node 2. The refraction coefficient F of each element for achieving the focusing affect depends upon the transmitter node 4 (e.g. gNB base station) angle with respect to the window and upon the coordinates of each element 20 within the window. The coordinates of an mth element 20 within the window may be denoted xm, ym, as shown in
The problem can be defined in two ways, according to the size of the window refractive aperture. While these approaches can provide the same benefits in terms of link budget enhancement, the way to leverage them are generally different. The first approach is a narrow-band beamforming approach and the second approach is a wide-band beamforming approach.
Narrow-band beamforming.
The multiple rays incident at the receive CPE antenna array must have a small delay spread, e.g. the difference between the earliest ray and the latest ray must be much smaller than the inverse of the bandwidth:
where c stands for the speed of light, B denotes the bandwidth and r is distance of the mth element 20 from the receive antenna of the receiver node 2.
As a consequence, there are two conditions that must be fulfilled by the setup where multiple incidence points occur in the Fixed Wireless Access system: at the refraction point (of the window) and on the receive point (of the antenna array).
Condition 1: At the receive antenna array.
The first condition, with reference to
This condition holds true for F=28 GHz, B=1 GHz, and N=64 (again, these example values are consistent with a typical mmWave system), where F is a frequency of the electromagnetic radiation transmitted by the transmitter node 4.
Condition 2: At the window.
The second condition is associated with the maximum delay difference that can occur between two refracted rays on the window. This depends on the window aperture size and the distance h between the window and the receive antenna array.
In this example, a rectangular refractive aperture on the window with dimensions L×L is assumed. Then it can easily be shown that the maximum possible delay between two refracted waves is the one between the closest point on the window with respect to the receive antenna array and the farthest one. This typically means that the difference is:
For a h=20 cm, B=1 GHz, L would thus be constrained below 3 cm, on a delay spread around 300 ns.
In the narrow-band beamforming case, it may be assumed that the multiple incoming rays have the substantially same magnitude, substantially the same absolute delays and different phases. In this case, a simple beamformer that applies phase shifts and combines the ray may be used.
The received signal at the receive antenna of the receiver node 2 may be defined as:
where:
Here, the antenna element weights Wk,p should be evaluated correctly.
In the above formula Γ(θ,ϕθgNB,ϕgNB) is the directive function of the window lens.
Based on spatial filtering theory, the weights Wk,p may be chosen to ensure a spatially matched filter, matched to spatial signature Γ(θ0).
In this example, it is assumed that Γ(θ0) may be digitized into a finite number of elements:
where Fk,p(θgNB, φgNB) holds the spatial signature:
As such, it may be proven that it is possible to build a spatially matched filter that is capable to capture the refracted energy from the window by using per-element (Wk,p) weights appropriately.
An alternative non-analytical way to derive the weights is by using an adaptive algorithm, for instance using a reference training signal, since it is not expected that the weights would change.
Wide-band beamforming.
In this case, if one of the previous conditions does not hold regarding the topology of the setup of the Fixed Wireless Access system, then different rays will have different delays.
It may generally not be sufficient to combine phase-offsetted replicas of the received signals. The constructive combining of the signals should have a delay-based beamformer, for example much like a RAKE receiver, employed in CDMA systems.
There are several solutions to cope with this problem.
Multi-Band Receiver
In this case, the receiver node 2 may split the band into multiple (e.g. M) narrower sub-bands, each one handled by a different receiver chain and beamformer. In this case, the narrow-band condition is imposed on each sub-band, rather than on the full band:
For each individual beamformer, over each sub-band, the philosophy of the narrow-band beamformer may be applied, as described above.
OFDM Receiver
In the case of an OFDM receiver, the multiple paths will experience a delay spread. In this case, the receiver will exhibit the following properties:
RAKE Beamformer
This is the most complex case, in which the beamformer may comprise multiple V-length finite impulse response (FIR) filters (instead of complex weights) whose outputs may then be combined. Then the problem becomes choosing the optimum V*N coefficients of the filter. The problem can still be resolved by imposing a similar (yet more complicated formula) to that described above, or by using an adaptive filter.
Embodiments of this disclosure may, for example, make use of the Metaradomes described in E. Özi, A. V. Osipov, T F. Eibert, Metamaterials for Microwave Radomes and the Concept of a Metaradome: Review of the Literature to implement the elements 2 described herein. Chapter 2 of this paper describes a radome as a protective cover between an antenna and its surroundings. It describes an ideal radome as fully transparent and lossless. A non-ideal radome can exhibit boresight error, caused by refraction of electromagnetic waves at the nonparallel interior and exterior sides of the radome wall with the result that a target is seen at an angularly changed, wrong position with respect to the antenna. The paper then describes the concept of metasurfaces, metasheets and metafilms, depending on whether the layer is penetrable or not, as well as the tunable materials including electrical tuning. It describes Huygens' metasheets that behave like a lens by locally controlling electric and magnetic currents induced on the surface. In chapter 7, this paper then goes on to describe metaradomes that use metasurfaces/sheets/films to improve the electromagnetic response of the enclosed antenna and eliminate the negative effects of conventional microwave radomes. This includes active radomes that are externally controlled. The potential applications described in the paper (see chapter 9) are around radomes with tailored transmission, absorption, and reflection properties to bring additional features and benefits such as correction of phase distortions, reduction of transmission losses, shaping the frequency dependence of the transmission, and making the radome tunable, including the ability of being switched on/off.
Embodiments of this disclosure may use similar metasheet/metafilm concepts, including electronically tunable surfaces to implement the elements 20. Note that embodiments of this disclosure relate to an application/use case which is not considered in E. Özi, A. V. Osipov, T F. Eibert, Metamaterials for Microwave Radomes and the Concept of a Metaradome: Review of the Literature.
Embodiments of this disclosure may be applied for any transceiver or communication system that implements communication through a barrier that can be transformed into an RF lens. Practical use may be limited to mmWave (and higher frequency) systems for which physical dimensions apply. One use case is a mmWave communications (Fixed Wireless Access/FWA) client use, where the device implements a 5G CPE/client modem. In conventional Fixed Wireless Access systems, a mmWave FWA modem is typically located outside of the customer premises with an Ethernet cable feeding into the house for further (WiFi based) distribution of the Internet connection. Embodiments of this disclosure can allow the modem to be placed inside of the customer premises, whereby a barrier (such as a wall, window or roof) is located in between the receive antenna array of the receiver node 2 and the transmitter node 4. According to embodiments of this disclosure, the losses associated with this barrier may be compensated for by the focusing effect described herein and a sufficient link budget may be maintained for successful communications.
In the present specific, yet illustrative, example, we assume the following parameters:
As a result, of these parameters, the following assumptions:
In this example, the barrier (e.g. window) may be sub-divided into sub-arrays 22 as shown in
As a result, in this example, a total sub-array size that is larger than the receive antenna of the receiver node 2 would result in RF energy loss.
As shown in
As shown in
In some embodiments, the elements may be passive elements, which refract the electromagnetic radiation be a fixed amount for focusing the electromagnetic radiation on a fixed location. However, as shown in
To support this tunability, each element 20 may include one or more microwave varactors 40. The varactors 40 may be used to tune the capacitance across pairs of capacitor plates 41 of the element 20, thereby to alter the refraction angle produced by that particular element 20. A controller may be provided for controlling the varactor(s) 40 of each respective element 20 in the barrier 10, collectively to cause the elements 20 to focus the electromagnetic radiation on a desired location in the customer premises. The capacitor plates 41 may, in some examples, be provided on opposite sides of the barrier (e.g. on opposite surfaces of a glass pane 30 of a window). In the embodiment shown in
Implementation of the resonant cells can be done using various materials including etched PCB with soldered discrete varactors mounted to a PCB or on a Transparent Conducting Film (TCF).
Accordingly, there has been described a wireless communication system and method. The system comprises user equipment comprising a receive antenna for receiving mmWave signals from a base station transmitter. The system also includes a barrier configured to focus electromagnetic radiation carrying the mmWave signals onto the receive antenna of the user equipment.
Although particular embodiments of this disclosure have been described, it will be appreciated that many modifications/additions and/or substitutions may be made within the scope of the claims.
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a 202000575 | Sep 2020 | RO | national |
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Number | Date | Country | |
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20220085514 A1 | Mar 2022 | US |