FR3082090A1 - A METHOD FOR AUTOMATIC RECONFIGURATION OF RADIO BASE STATIONS IN THE CONTEXT OF LSA - Google Patents

Abstract

the state of the art of the LSA, including the ETSI standards, does not describe a method how the radio parameters of the radio base stations of the secondary user network located in the vicinity of one or more protection zones are reconfigured to ensure the protection of said areas. The present invention describes a method; this method makes it possible to determine and then adjust the maximum authorized transmission powers of the radio base stations of the secondary user network when said stations are located in the vicinity of one or more protection zones of the primary user.

Description

A method for automatic reconfiguration of radio base stations in the context of the LSA

DESCRIPTION OF THE INVENTION

Description of the figures

Figure 1 shows an example of state-of-the-art LSA architecture.

Figure 2 shows an example of spectrum preemption according to the state of the art of the LSA.

FIG. 3 describes an example of a sequence of messages making it possible to perform spectrum preemption in accordance with the state of the art of the LSA illustrated by FIGS. 1 and 2.

Figures 4 and 5 show two examples of an LSA architecture to which an REM component is added to allow automatic reconfiguration of radio base stations according to the principle of the invention below.

FIG. 6 illustrates the protection points (p) situated within a zone to be protected, the protected frequencies (f) operated by the network of the primary user inside said zone and the thresholds protection Q _P f, associated with each point (p) for each frequency (f).

Description of the state of the art of a radio environment map (REM)

A radio environment map or REM (Radio Environment Map), representing a dynamic, multi-dimensional, real-time radio environment, can be used to help the decision-making process in many telecommunications applications such as as the configuration, optimization, repair of radio networks, dynamic radio planning, or even the sharing of radio spectrum for civil, security and defense telecommunications.

The radio environment map or REM can be designed as a database containing information on the radio environment, par. eg, the power received from a radio frequency (RF) signal, the weakening of a radio frequency (RF) signal related to its propagation in the surrounding physical environment, or a level of radio frequency (RF) interference ) aggregated and represented in spatial, temporal and frequency dimensions.

The information that will make up the radio environment map is calculated for the spatial, temporal and frequency dimensions using advanced RF propagation models. These complex RF propagation models take into account a multitude of physical phenomena linked to the propagation of RF signals (see FR3020530).

The radio environment map or REM is constructed using information on the deployment topology of radio transmitters and receivers, using their technical characteristics and RF configurations, using data on the surrounding environment such as digital terrain models, land cover models or above-ground dimensions, digital building models, static models of climate, soil refractivity, air permittivity, and general, of any data that interferes with the propagation of RF signals (see FR3020529).

In addition, the radio or REM environment map is enriched with punctual RF measurements measured in the field; these real measurements can be used to calibrate the RF propagation models, continuously and in real time (see FR3039961).

The radio or REM environment map can be viewed, for example, using a GIS (Geographic Information System) interface, to show information in spatial, temporal and frequency dimensions.

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The concept of the radio environment map or REM has been the subject for many years of mainly academic work with no industrialization objective.

However, to be usable in an industrial field, such as the field of civil telecommunications, security and defense, the radio environment map or REM needs to obtain reliable results representing a radio environment close to reality.

Description of the state of the art of Licensed Shared Access (LSA)

In order to maximize the use of the spectrum, new models allowing the spectrum to be shared between different users have been defined.

For example, the LSA makes it possible to share the spectrum between primary and secondary users.

Primary users have access to priority spectrum over secondary users.

When primary users use spectrum in a given geographical area, the transmitters of secondary users, (for example radio base stations, in the case of a mobile operator) likely to interfere in this geographical area are reconfigured so as to do not generate interference on primary users.

Alternatively and when the primary user uses the same radio technology as the secondary user, it may be advantageous to reuse the secondary user network for the benefit of the primary user.

Figure 1 shows an example of state-of-the-art LSA architecture.

In this figure, a primary user is connected to an LR ("LSA Repository").

The LR is connected to LCs ("LSA Controller"). Each LC is responsible for processing preemption requests from the LR and identifying the network elements to be reconfigured so as not to generate interference on the primary user; this LC task can also be partially performed by the NM ("Network Manager"), depending on the functional breakdown chosen by the operator.

The NM, radio base stations (eg eNodeBs or "eNBs"), are the elements of the secondary user network. This network can for example be a 3GPP LTE network.

The NM is the entity used to reconfigure radio base stations.

For more information on the LSA see the following ETSI standards:

ETSI TS 103 154 “System requirements for operation of Mobile Broadband Systems in the 2300 MHz -2400 MHz band under LSA”, TS 103 235 “System Architecture and High-Level Procedures for operation of LSA in the 2300 MHz-2400 MHz band”,

ETSI TS 103 235 “System Architecture and High-Level Procedures for operation of LSA in the 2300 MHz-2400 MHz band”,

ETSI TS 103 379V1.1.1 “Information elements and protocols for the interface between LSA Controller (LC) and LSA Repository (LR) for operation of Licensed Shared Access (LSA) in the 2300 MHz-2400 MHz band”,

ETSI TS 128 301 V14.0.0 “LTE; Telecommunication management; Licensed Shared Access (LSA) Controller (LC) Integration Reference Point (IRP); Requirements (3GPP TS 28.301 version 14.0.0 Release 14) ”,

ETSI TS 128 302 V14.0.0 “TE; Telecommunication management; Licensed Shared Access (LSA) Controller (LC) Integration Reference Point (IRP); Information Service (IS) (3GPP TS 28.302 version 14.0.0 Release 14) ”,

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ETSI TS 128 303 V14.0.0 “LTE; Telecommunication management; Licensed Shared Access (LSA) Controller (LC) Integration Reference Point (IRP); Solution Set (SS) definitions (3GPP TS 28.303 version 14.0.0 Release 14) ”.

Figure 2 shows an example of spectrum preemption according to the state of the art of the LSA.

The left side of Figure 2 shows the network status of a secondary user when there is no spectrum preemption.

The circles around the radio base stations indicate their respective radio coverage.

In this figure, a radio base station is colored white if it is used by the network of the secondary user. A radio base station is colored gray if it is switched off.

The dotted rectangle indicates a pre-emption geographic area, over which the primary user wishes to have access to the spectrum.

On the left side of Figure 2, the preemption request has not yet been processed. As a result, all radio base stations can be used by the secondary user network.

The right side of Figure 2 shows the network status after the preemption request has been processed.

The radio base stations 1, 2, and 3 are switched off so as not to generate interference on the pre-emption geographical area illustrated in dotted lines.

Radio base stations 4 and 5 are still authorized to transmit, but their transmission power has been reduced in order not to generate interference in the geographic area of preemption.

FIG. 3 describes an example of a sequence of messages making it possible to carry out the network reconfiguration illustrated by FIGS. 1 and 2, in an LSA architecture.

A primary user sends a spectrum preemption request to the LR. The LR spectrum preemption request details spectrum preemption with information such as geographic area, maximum interference level tolerated by the primary user.

the protection zones are formatted as standardized information elements of the LSA Spectrum Resource Availability Information object (LSRAI) as defined by the ETSI standard TS 103 379 and then sent via the LSA-1 interface to the LC;

The standard information elements of the relevant LSA Spectrum Resource Availability Information (LSRAI) object can be defined as follows:

the object contains one or more geographic zones corresponding to the radio coverage to be protected, each zone of the object is of "protection" type, each zone contains:

o a contour in the form of a polygon, and o the frequencies used by the primary user in said area, and o the level of protection of said area and set in dBm / MHz, and o the time interval (s) during which said area should be protected.

LR sends LSA Spectrum Resource Availability Information (LSRAI) to LC describing resource information that can either be used by the secondary user or restricted for use

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The message transmitted by the LR to the LC can for example correspond to the “LSRAI Notification” message as defined in the document ETSITS 103 379.

The secondary user, the LC in the case of the LSA, identifies the new parameters of the secondary user network based on the new LSRAI information received.

The parameters of the secondary user network which can be modified by the LC or via the NM may consist, for example, for a given radio base station of the network, by:

A modification of the transmission power,

A modification of the antenna parameters,

A modification of the access priority parameters,

A modification of the neighbor cell list (or “neighbor cell list”),

A modification of the "hand over" parameters,

A change in the identifier of a cell associated with this radio base station.

The identification by the secondary user, the LC in the case of the LSA, of these new parameters of the network of the secondary user may have in particular the objective:

to modify the radio coverage of a radio base station so that it covers all or part of the pre-emption geographical area, and is thus able to serve the users of the primary user's network, when this base station radio is located in or near the pre-emption geographic area.

to modify the coverage of a radio base station in order to limit the interference of this radio base station on the geographic preemption area, when this radio base station is identified as being too far from the geographic preemption area to be able to be useful for the primary user.

to modify the access of the terminals to the cells of a radio base station in order to favor the users of the primary user, when this radio base station is located in or near the preemption zone.

Description of the LC alternative in the state of the art of Licensed Shared Access (LSA)

In step 3, the secondary user, the LC in the case of the LSA, transmits these new parameters to the NM. When the NM is as defined in a 3GPP architecture, these parameters of the secondary user network can be supplied to the NM through the message "cellsConstraintsUpdate" as defined in the document ETSI TS 128.302. The NM then reconfigures the radio base stations in the secondary user network according to these parameters.

Once the secondary user network has been reconfigured, a confirmation is sent to the primary user, via the LC and LR (steps 4 to 6).

The primary user can then connect to radio base stations that cover the preemption area, without receiving interference from the secondary user.

Description of the NM alternative in the state of the art of Licensed Shared Access (LSA)

In an alternative to step 3 of the diagram illustrated in FIG. 3, the spectrum preemption request is transmitted from LC to NM through the message "notifyZoneCreation" or the message "notifyZoneModification" as defined in the document ETSI TS 128.302. In this alternative, the new network parameters

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State of the art Licensed Shared Access (LSA) limitation

However, the state of the art of the LSA including the ETSI standards cited above does not describe a method how the radio parameters of the radio base stations of the secondary user network located in the vicinity of one or more zones of protection are reconfigured to ensure the protection of said areas.

Description of the invention

The present invention describes a method; this method makes it possible to determine and adjust the maximum authorized transmission powers of the radio base stations of the secondary user network when said stations are located in the vicinity of one or more protection zones of the primary user (for example less than 40 km from a particular point in one of the areas to be protected).

The REM (s) located in the LC (s) (as illustrated in FIG. 4) or in the NM (s) (as illustrated in FIG. 5) have the function of determining and then adjusting the transmission powers of said radio base stations in order to limit interference to the admissible protection thresholds which are generated by said stations on the protection zones; each station has its power adjusted by the REM, which is responsible for said station.

The REM (s) determine or adjust the transmission powers of the radio base stations of the secondary user's network in order to satisfy the following constraints:

i. for a zone defined as being to be protected and called a protection zone, a protection threshold to be respected in order to protect said zone is applied to each of the protection points situated inside the protection zone for a given frequency, and ii. said protection threshold corresponds to the admissible limit of radio interference received from radio base stations of the secondary user network located in the vicinity of said area at said point at said frequency, and iii. none of the said protection thresholds situated within the said zone may be exceeded following the allocation of the transmission powers of the radio base stations located in the vicinity of the said zone, and where iv. each protection point (p) located within the protection zone is associated with one or more frequencies to be protected (f), and where

v. the combination of protection point (p) and frequency to be protected (f) is called protection constraint <p, f>, and where vi. for each protection constraint (p, f), there is a number N _p , f corresponding to the total number of radio base stations in the vicinity of this protection point (p) authorized to transmit at the frequency (f), and where vii. Q _p , f is the protection threshold for point (p) at frequency (f).

FIG. 6 illustrates the protection points (p) located inside a protection zone, the frequencies to be protected (f) which are operated by the network of the primary user inside said zone and the protection thresholds Q _p , f associated with each point (p) for each frequency (f).

the interference received from radio base stations in the secondary user's network on the protection zones is calculated by the REM (s) located in the LC (s) (as illustrated in Figure 4) or in the NM (s) (as illustrated by Figure 5) using RF propagation models, digital terrain models, land cover or above-ground footprint models, digital building models, static climate, soil refractivity models , the permittivity of air, and in general, of any data that interferes with the propagation of RF signals.

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The method which consists in adjusting the transmission powers of the radio base stations of the secondary user network is characterized by the following operations:

1. in the case where several REMs share the same geographical area, Each REM exchanges with the other REMs in a synchronized manner the information of the radio base stations of the network of the secondary user for which the REM is responsible for adjusting the powers of transmission; the information exchanged from said stations is:

the transmission power at the output of the power amplifier configured by the secondary operator for each frequency (f) operated, and the parameters of the antenna elements which are the latitude, the longitude, the height above the ground, the azimuth, the "tilt", the horizontal and vertical radiation patterns, if necessary the "beamforming" parameters, and

2. for each protection constraint (p, f) of each protection zone, each REM must individually determine the transmission power on the frequency (f) not to be exceeded for each base station deployed in the vicinity of said zone of such so that the contribution to interference from said station corresponding to the transmission power minus the radio link budget between said station and point (p) is equal to or less than 1 / N _p , f of the total admissible protection threshold Q _p , f of said constraint; it should be noted that the power cannot be greater than the maximum power at the output of the amplifier configured by the secondary operator for the frequency (f) operated, and

3. each REM individually must adjust the transmission power for the operating frequency (f) of each base station by taking the smallest power determined by the previous step and correspond to the admissible power for the constraint (p, f) the most restrictive for said station.

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A method for automatic reconfiguration of radio base stations in the context of the LSA

Claims (3)

(CLAIM 1) The method which consists in adjusting the transmission powers of the radio base stations of the secondary user network is characterized by the following operations: 1. in the case where several REMs share the same geographical area, Each REM exchanges with the other REMs in a synchronized manner the information of the radio base stations of the network of the secondary user for which the REM is responsible for adjusting the powers of transmission; the information exchanged from said stations is: the transmission power at the output of the power amplifier configured by the secondary operator for each frequency (f) operated, and the parameters of the antenna elements which are the latitude, the longitude, the height above the ground, the azimuth, the "tilt", the horizontal and vertical radiation patterns, if necessary the "beamforming" parameters, and 2. for each protection constraint (p, f) of each protection zone, each REM must individually determine the transmission power on the frequency (f) not to be exceeded for each base station deployed in the vicinity of said zone of such so that the contribution to interference from said station corresponding to the transmission power minus the radio link budget between said station and point (p) is equal to or less than 1 / Np, f of the total admissible protection threshold Qp, f of said constraint; it should be noted that the power cannot be greater than the maximum power at the output of the amplifier configured by the secondary operator for the frequency (f) operated, and 3. each REM individually must adjust the transmission power for the operating frequency (f) of each base station by taking the smallest power determined by the previous step and correspond to the admissible power for the constraint (p, f) the most restrictive for said station. (CLAIM 2) The method according to claim 1 in which said or said REMs determine and then adjust the transmission powers of the radio base stations of the secondary user's network in order to satisfy the following constraints: i. for a zone defined as being to be protected and called a protection zone, a protection threshold to be respected in order to protect said zone is applied to each of the protection points situated inside the protection zone for a given frequency, and ii. said protection threshold corresponds to the admissible limit of radio interference received from radio base stations of the secondary user network located in the vicinity of said area at said point at said frequency, and iii. none of the said protection thresholds situated within the said zone may be exceeded following the allocation of the transmission powers of the radio base stations located in the vicinity of the said zone, and where iv. each protection point (p) located within the protection zone is associated with one or more frequencies to be protected (f), and where v. the combination of protection point (p) and frequency to be protected (f) is called protection constraint <p, f>, and where vi. for each protection constraint (p, f), there is a number N _p , f corresponding to the total number of radio base stations in the vicinity of this protection point (p) authorized to transmit at the frequency (f), and or Vii. Q _p , f is the protection threshold for point (p) at frequency (f). (CLAIM 3) The method according to claim 1, in which said REM or said REMs are located in the LC (s) or in the NM (s) and have the function of determining and then adjusting the transmission powers of said 5 radio base stations in order to limit interference the admissible protection thresholds which are generated by said stations in the protection zones; each station has its power adjusted by the REM, which is responsible for said station. (CLAIM 4) The method according to claim 1 wherein said interference received from radio base stations of the secondary user's network on the protection zones is calculated by the REM (s) located in the LC (s) (as illustrated in FIG. 4) or in the NM (s) (as illustrated in FIG. 5) using RF propagation models, digital terrain models, land cover or above-ground congestion models, digital frame models, static models of climate, ground refractivity, air permittivity, and in general, any data that interferes with the propagation of RF signals.